Manufacturing method for light emitting device, light emitting device, and hybrid light emitting device

ABSTRACT

A manufacturing method for a light emitting device, a light emitting device, and a hybrid light emitting device, the manufacturing method comprises the following steps: step S 1 : disposing a mask plate having a plurality of hollow portions on a substrate; step S 2 : by using a solution method, applying ink on a surface of the substrate through the hollow portions; and step S 3 : drying or solidifying the ink on the surface of the substrate to form a light emitting layer or a functional layer.

TECHNICAL FIELD

The disclosure relates to the field of optical technologies, and in particular, to a manufacturing method for a light emitting device, the light emitting device, and a hybrid light emitting device.

BACKGROUND

Along with the continuous development of science and technology, requirements of people on display quality is continuously increasing, quantum dots light emitting diode (QLED) display is known as the most representative display technology in future for its high color purity, color saturation and wide color gamut. Currently, QLED device is mainly manufactured by solution method, such as inkjet printing, silk-screen printing, spin-coating, slit-coating, and spray-coating, because a displayed pixel is very small, coating of sub-pixel generally adopts inkjet printing process to realize the selective coating, namely, in RGB sub-pixel grooves constructed by pixel separating structure, nozzles are used for successively printing R, G, B quantum dot material inks. Because the efficiency of existing blue light QLED device is low, it is somewhat difficult to construct the RGB display of the QLED device by directly using quantum dots, but developments of traditional blue light LED and OLED are more mature, so a mode of realizing the RGB display by RG quantum dots optically combined with LED or OLED having electrically blue light may be rapidly realized in a short time.

However, in the above inkjet printing process, morphology of a droplet sprayed by the nozzle is very unstable, many small droplets may be usually observed around a main droplet, the dispersed small droplets are easy to deviate from their original positions, and fall into neighboring sub-pixel areas, so that falling quantity of material in each sub-pixel is different or a color mixture problem occurs, thereby the final performance of the light emitting device is affected or color difference problem is generated, leading to a reduced product yield.

The OLED generally uses an evaporation method to prepare the above electroluminescence device, namely, an upper space of a substrate is covered by a mask plate and multiple times of the vacuum hot evaporation are performed to prepare the RGB pixels, for example, when the R pixels are evaporated, the positions corresponding to the GB pixels are covered by the mask plate so as not to be evaporated, in the above method, utilization rate of materials is relative low, the cost is extremely high, based on the above disadvantage, an solution method for manufacturing the above OLED electroluminescent device with RGB pixels is extensively researched, in order to counter against the QLED electroluminescent device which has advantage of solution processable method. The QLED device with wide color gamut, accurate and controllable colors and the like is known as the optimal display technology of the next generation. No matter it is the OLED display which continuously occupies traditional LCD display market, or the QLED display which is vigorously developed in order to replace the OLED so that the display technology can be directly transited from LCD to QLED, manufacturing process of the solution method is the key of the current research.

However, regarding the spray-coating process of the solution method, because the material orientation of the spraying device is low, it is only suitable for area coating, and is not suitable for point coating; regarding the inkjet printing process of the solution method technology, in order to guarantee the injection precision of ink, a precision inkjet printing device is generally needed, therefore the device investment is too expensive.

During the preparation process of an optical quantum dot color film, a black matrix or a pixel separating structure manufactured by yellow light process is complicated in process and expensive in cost. The investment of the precision inkjet printing device is also expensive, the difficulty is increased for popularization of a new technology.

SUMMARY

The disclosure mainly aims to provide a manufacturing method for a light emitting device, a light emitting device and a hybrid light emitting device, and solve problem in the prior art that the light emitting device has a color difference arising from color mixture.

In order to achieve the above purpose, according to one aspect of the disclosure, a manufacturing method for a light emitting device is provided, the manufacturing method includes the following steps: step S1, a mask plate having a plurality of hollow portions is disposed on a substrate; step S2: by solution method, ink is applied on the surface of the substrate after passing through the hollow portions; and step S3: the ink is dried or solidified on the surface of the substrate to form a light emitting layer or a functional layer.

Further, the ink is quantum dot material ink, the manufacturing method further includes a process of at least one time of repeatedly performing the step S1 to the step S3, in each time of the repeated process, the hollow portions of the used mask plate correspond to the different areas of the substrate, the light emitting colors of the used inks are different.

Further, the mask plate in the step S1 has a modified surface, the modified surface includes a surface of the mask plate away from the substrate, the modified surface has hydrophilicity or hydrophobicity; the ink used in the step S2 and the modified surface have different hydrophilicity-hydrophobicity.

Further, the modified surface further includes a surface of the mask plate adjacent to the substrate.

Further, when the modified surface is a hydrophobic surface, the manufacturing method further includes a process of forming the modified surface: step S01, the mask plate is immerged in solution with a hydrophobic material, so that the hydrophobic material is fixed on the surface of the mask plate, preferably the hydrophobic material is a fluoric silane coupling agent; and step S02, the mask plate fixed with the hydrophobic material is separated from the solution, and drying treatment is performed on the mask plate, so as to form the modified surface with hydrophobicity.

Further, the manufacturing method further includes a process of pre-processing the mask plate, the pre-processing process includes the following step: ultraviolet ozone photolysis oxidization is performed on the surface of the mask plate, so that the hydrophilic surface of the mask plate is completely exposed.

Further, the substrate in the step S1 is provided with a pixel separating structure, and the pixel separating structure is provided with multiple mutually separated sub-pixel areas, and the hollow portions are disposed corresponding to each sub-pixel area; in the step S2, the ink enters the corresponding sub-pixel areas after passing through the hollow portion.

Further, the surface of the substrate in the step S1 has hydrophilic areas and hydrophobic areas, the hollow portions are disposed corresponding to the hydrophilic areas or the hydrophobic areas; in the step S2, the hydrophobic ink enters the hydrophobic area after passing through the hollow portion, or the hydrophilic ink enters the hydrophilic area after passing through the hollow portion.

Further, the ink is any one of hole injection material ink, hole transporting material ink, electron injection material ink or electron transporting material ink, in the step S3, the ink is dried, so as to correspondingly form a hole injection layer, a hole transporting layer, an electron injection layer or an electron transporting layer; or the ink is quantum dot material ink or organic light emitting material ink, in the step S3, the ink is dried, so as to correspondingly form a quantum dot light emitting layer or an organic light emitting layer.

Further, the ink is electrode material ink, in the step S3, the ink is dried, so as to correspondingly form an electrode layer.

Further, the ink is any one of hole injection material ink, hole transporting material ink, electron injection material ink, electrode material ink or electron transporting material ink, in the step S3, the ink is solidified, so as to correspondingly form a hole injection layer, a hole transporting layer, an electron injection layer, an electrode layer or an electron transporting layer; or the ink is quantum dot material ink or organic light emitting material ink, in the step S3, the ink is solidified, so as to correspondingly form a quantum dot light emitting layer or an organic light emitting layer.

Further, in the step S2, a spray-coating process or an inkjet printing process is used so that the ink is disposed on the surface of the substrate after passing through the hollow portions, and the spray-coating process is ultrasonic spray-coating preferably.

According to another aspect of the disclosure, a light emitting device is provided, the light emitting device is prepared by the above manufacturing method, the light emitting device is an electroluminescence device or a photoluminescence device.

According to another aspect of the disclosure, a hybrid light emitting device is further provided, the hybrid light emitting device includes an electroluminescence device and a photoluminescence device disposed at the light emitting side of the electroluminescence device, the electroluminescence device and/or the photoluminescence device is prepared by the manufacturing method.

According to another aspect of the disclosure, a surface modified mask plate is further provided, the surface modified mask plate is provided with multiple hollow portions, the surface modified mask plate is provided with a modified surface, the modified surface includes a first modified surface and a second modified surface, the first modified surface is disposed around the hollow portions, the modified surface except the first modified surface is the second modified surface, and the first modified surface and the second modified surface are different and are respectively selected from one of hydrophilic surface and hydrophobic surface.

According to another aspect of the disclosure, a surface modifying method for the mask plate is further provided, the surface modifying method includes the following step: modification is performed on the surface of the mask plate with multiple hollow portions, so as to form the modified surface, the modified surface includes a first modified surface and a second modified surface, the first modified surface is disposed around the hollow portions, the modified surface except the first modified surface is the second modified surface, and the first modified surface and the second modified surface are different and respectively have hydrophilicity or hydrophobicity.

Further, the surface modifying method includes the following steps: step S01′, the mask plate is immerged in solution with a hydrophobic material, so that the hydrophobic material is fixed on the surface of the mask plate, preferably the hydrophobic material is a fluoric silane coupling agent; and step S02′, the mask plate fixed with the hydrophobic material is separated from the solution, and drying treatment or solidifying treatment is performed on the mask plate; and step S03′, a first photomask is disposed on the first surface of the mask plate, the first photomask is formed with multiple first shielding portions and a first light transmitting portion connected to each first shielding portion, the first shielding portions correspond to the hollow portions in a one-to-one way, and the area of each first shielding portion is greater than the corresponding area of each hollow portion, ultraviolet ozone photolysis oxidization is performed on the first surface of the mask plate by the first photomask, and the ultraviolet ozone photolysis oxidization is performed on the second surface of the mask plate opposite to the first surface, so as to form the second modified surface with hydrophilicity, the rest surface of the mask plate forms the first modified surface with hydrophobicity; or a second photomask is disposed on the mask plate, the second photomask is formed with multiple second light transmitting portions and a second shielding portion connected to each second light transmitting portion, and the second light transmitting portions correspond to the hollow portions in a one-to-one way, and the area of each second light transmitting portion is greater than the corresponding area of each hollow portion, the ultraviolet ozone photolysis oxidization is performed on the mask plate, so that the surface of the mask plate corresponding to the second light transmitting portions forms the first modified surface with hydrophilicity, and the rest surface of the mask plate forms the second modified surface with hydrophobicity.

According to another aspect of the disclosure, a manufacturing method for an electroluminescence device is further provided, the manufacturing method includes the following steps: step S1′, a first electrode substrate with a pixel separating structure is provided, the pixel separating structure is provided with multiple mutually separated sub-pixel areas; step S2′, the above surface modified mask plate is disposed on one side of the first electrode substrate having pixel separating structure, the first modified surface of the surface modified mask plate is disposed away from the first electrode substrate, and one or more hollow portions of the surface modified mask plate are disposed corresponding to each sub-pixel area of at least partial sub-pixel areas; step S3′, by solution method, the ink having the same hydrophilicity-hydrophobicity as the first modified surface of the surface modified mask plate enters the corresponding sub-pixel areas through the hollow portions; and step S4′, the ink in the sub-pixel areas is dried or solidified, so as to form a light emitting layer or a functional layer.

Further, the ink is any one of hole injection material ink, hole transporting material ink, electron injection material ink or electron transporting material ink, in the step S4′, the ink is dried, so as to correspondingly form a hole injection layer, a hole transporting layer, an electron injection layer or an electron transporting layer; or the ink is any one of quantum dot material ink and organic light emitting material ink, in the step S4′, the ink is dried, so as to correspondingly form a quantum dot light emitting layer or an organic light emitting layer.

Further, when the ink is quantum dot material ink, the manufacturing method further includes a process of at least one time of repeatedly performing the step S2′ to the step S4′, in each time of the repeated process, the hollow portions of the used surface modified mask plate correspond to the different sub-pixel areas, the light emitting colors of the used inks are different.

Further, in the step S3′, a spray-coating process or an inkjet printing process is used so that the ink enters the sub-pixel areas after passing through the hollow portion, and the spray-coating process is ultrasonic spray-coating preferably.

Further, an ultrasonic frequency used by the ultrasonic spray-coating is 45-180 kHz.

Further, after the step S4′, the manufacturing method further includes the following steps: step S5′, when the light emitting layer is formed in the step S4′, one side of the light emitting layer away from the first electrode substrate is provided with a second electrode, or step S5′, when the functional layer is formed in the step S4′, the functional layer is a first injection layer or a first transporting layer, one side of the first injection layer or the first transporting layer away from the first electrode substrate is provided with the light emitting layer, and one side of the light emitting layer away from the first electrode substrate is provided with the second electrode.

Further, when the functional layer is formed in the step S4′, and the functional layer is the first injection layer, in the step S5′, the manufacturing method further includes the following steps: before a process of disposing the light emitting layer, repeatedly performing the steps from S2′ to S4′, so that the surface of the first injection layer is provided with first transporting layer; after the process of disposing the light emitting layer, repeatedly performing the steps from S2′ to S4′, so that the surface of the light emitting layer is provided with a second transporting layer; and after a process of disposing the second transporting layer, repeatedly performing the steps from S2′ to S4′, so that the surface of second transporting layer is provided with second injection layer.

According to another aspect of the disclosure, a manufacturing method for a quantum dot film is further provided, the manufacturing method for the quantum dot film includes the following steps: step a, hydrophilic areas and hydrophobic areas are formed on a first surface of a light transmitting substrate; step b, the surface modified mask plate with multiple hollow portions are disposed on the first surface of the light transmitting substrate, and the hollow portions of the surface modified mask plate are disposed corresponding to the hydrophilic areas or the hydrophobic areas, the surface modified mask plate is provided with a modified surface, the modified surface includes a first modified surface and a second modified surface, the first modified surface is disposed around the hollow portions, the modified surface except the first modified surface is the second modified surface, and the first modified surface and the second modified surface are different and are respectively selected from one of a hydrophilic surface and a hydrophobic surface, and the first modified surface is positioned at one side of the surface modified mask plate away from the first surface of the light transmitting substrate; step c, the first modified surface is the hydrophobic surface, so hydrophobic quantum dot ink enters the hydrophobic area after passing through the hollow portion, or the first modified surface is the hydrophilic surface, so hydrophilic quantum dot ink enters the hydrophilic area after passing through the hollow portion; and step d, the quantum dot ink in the hydrophilic areas or the hydrophobic areas is dried. The above quantum dot ink is the foresaid quantum dot material ink.

Further, the step a includes the following steps: step S001, the surface of the light transmitting substrate is provided with a raw material including a first reaction raw material; step S002, the first reaction raw material positioned in a first area is covered, and ultraviolet irradiation is performed on the first reaction raw material positioned in a second area, the first reaction raw material forms a second shielding area in the second area; step S003, the first reaction raw material in the first area is removed, the first area and the second shielding area are provided with a second reaction raw material; step S004, the second reaction raw material positioned in the second shielding area is covered, and the ultraviolet irradiation is performed on the second reaction raw material positioned in the first area, the second reaction raw material positioned forms a first shielding area in the first area, and the second reaction raw material on the second shielding area is removed, the first reaction raw material and the second reaction raw material are respectively selected from one of hydrophilic reactant and hydrophobic reactant, and the hydrophobicity-hydrophilicity of two reactants are opposite, the first shielding area and the second shielding area correspondingly form the hydrophilic areas and the hydrophobic areas.

Further, the manufacturing method further includes a process of preparing a surface modified mask plate: step S01, the mask plate is immerged in solution with a hydrophobic material, so that the hydrophobic material is fixed on the surface of the mask plate, preferably the hydrophobic material is a fluoric silane coupling agent; and step S02, the mask plate fixed with the hydrophobic material is separated from the solution, and drying treatment or solidifying treatment is performed on the mask plate; and S03, a first photomask is disposed on the first surface of the mask plate, the first photomask is formed with multiple first shielding portions and a first light transmitting portion connected to each first shielding portion, the first shielding portions correspond to the hollow portions in a one-to-one way, and the area of each first shielding portion is greater than the area of each hollow portion corresponding to the first shielding portion, ultraviolet ozone photolysis oxidization is performed on the first surface of the mask plate through the first photomask, and the ultraviolet ozone photolysis oxidization is performed on the second surface of the mask plate opposite to the first surface, so as to form a second modified surface with hydrophilicity, the rest surface of the mask plate forms a first modified surface with hydrophobicity; or a second photomask is disposed on the mask plate, the second photomask is formed with multiple second light transmitting portions and a second shielding portion connected to each second light transmitting portion, and the second light transmitting portions correspond to the hollow portions in a one-to-one way, and the area of each second light transmitting portion is greater than the area of each hollow portion corresponding to the second light transmitting portion, the ultraviolet ozone photolysis oxidization is performed on the mask plate, so that the surface corresponding to the second light transmitting portions of the mask plate forms the first modified surface with hydrophilicity, and the rest surface of the mask plate forms the second modified surface with hydrophobicity.

Further, a spray-coating process or an inkjet printing process is used in the step c so that the quantum dot ink enters the hydrophilic area or the hydrophobic area after passing through the hollow portion.

Further, the spray-coating process is ultrasonic spray-coating.

Further, the first surface forms multiple hydrophilic areas and multiple hydrophobic areas, and each hydrophilic area and each hydrophobic area are alternately arranged.

Further, the hydrophilic quantum dot ink includes hydrophilic quantum dots, and the hydrophilic quantum dots are quantum dots of which surface ligands contain hydrophilic groups; and the hydrophobic quantum dot ink includes a hydrophobic quantum dots, and the hydrophobic quantum dots are quantum dots of which surface ligands contain hydrophobic groups.

Further, the quantum dots in the quantum dot ink is red quantum dots and/or green quantum dots.

According to another aspect of the disclosure, a quantum dot film is further provided, the quantum dot film is manufactured by the above manufacturing method.

According to another aspect of the disclosure, a display device is further provided, the display device includes an electroluminescence device and a quantum dot film disposed at the light emitting side of the electroluminescence device, the quantum dot film is the foresaid quantum dot film. Applying the technical scheme of the disclosure, a manufacturing method for a light emitting device is provided, according to the manufacturing method, a mask plate with multiple hollow portions are disposed on a substrate, and ink is applied on the surface of the substrate after passing through the hollow portions by a solution method, the ink on the surface of the substrate is dried or solidified, so as to form a light emitting layer or a functional layer, so the mask plate is used for preventing the ink from being dispersed to other color areas, the color mixture problem is effectively avoided, and the color precision of the light emitting device is improved.

Besides the above described purposes, features and advantages, the disclosure further has other purposes, features and advantages. The disclosure is further described in detail below in combination with the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which constitute a part of this application, are used to provide a further understanding of the disclosure, and the exemplary embodiments of the disclosure and the description thereof are used to explain the disclosure, but do not constitute improper limitations to the disclosure. In the drawings:

FIG. 1 shows a flow schematic diagram of a manufacturing method of a light emitting device provided by an embodiment of the disclosure;

FIG. 2 shows a top view structure schematic diagram of a surface modified mask plate provided by an embodiment of the disclosure;

FIG. 3 shows a flow schematic diagram of a manufacturing method of an electroluminescence device provided by an embodiment of the disclosure;

FIG. 4 shows an optical microscope picture of a sub-pixel area after executing the step S1306 in an embodiment 13 of the disclosure; and

FIG. 5 shows a flow schematic diagram of a manufacturing method of a quantum dot film provided by an embodiment of the disclosure.

DETAILED DESCRIPTION OF THE EMBODIMENTS

It is to be noted that the embodiments in the disclosure and the features in the embodiments may be mutually combined in the case without conflicting. The disclosure is described in detail below with reference to the drawings in combination with the embodiments.

In order to make those skilled in the art to understand the scheme of the disclosure better, the technical scheme in the embodiment of the disclosure is clearly and completely described below in combination with the drawings in the embodiment of the disclosure, apparently, the described embodiments are only a part of the embodiments of the disclosure, but are not all of the embodiments. Based on the embodiments in the disclosure, all other embodiments acquired by those of ordinary skill in the art under the precondition without the creative work fall within the scope of protection of the disclosure.

It is to be noted that terms ‘first’, ‘second’ and the like in the description and claims and the above drawings of the disclosure are used for distinguishing similar objects, and are not intended to describe a specific sequence or a precedence order. It is to be understood that such used data may be interchanged in a proper situation, so that the embodiments of the disclosure described herein may be implemented in sequences besides those graphically-represented or described herein. Besides, terms ‘include’ and ‘have’ and any variations thereof are intendent to cover the non-exclusive inclusion, for example, a process, a method, a system, a product or a device containing a series of steps or units is not limited to clearly list those steps or units, but may include other steps or units which are not clearly listed or inherent to these process, method, product or device.

The quantum dot material ink in the application may be also named as quantum dot ink, the ink includes water-like ink with a smaller viscosity, besides, the ink also includes glue-like ink with a larger viscosity.

The meaning of hydrophilicity and hydrophobicity in the application is that the hydrophilic ink is an ink with polar group molecules, has large affinity to water, may absorb water molecules, or can be dissolved in water. The hydrophilic surface is a surface of a solid material formed by the molecules with polar groups, and it is easily moistened by water. The feature of easily moistened by water is the hydrophilicity of a substance. In chemistry, the hydrophobicity is a physical property that a molecule (hydrophobe) is repelled with water, the hydrophobic ink is an ink which contains the molecules with the physical property of repelling water, the hydrophobic surface is a surface of a solid material formed by the molecules with the physical property of repelling water. For example, when a droplet (aqueous) spreads and moistens a relative larger area, and the contact angle is less than 90 degrees, such surface is defined as hydrophilic surface. When the droplet forms a sphere, and nearly does not contact with the surface, the contact angle of the droplet is greater than 90 degrees, such surface is defined as hydrophobic surface.

As the introduction in the background, in the current inkjet printing technology, because the ink droplets sprayed by the nozzle are dispersed, the dispersed small droplets are easy to deviate from original positions, and fall into neighboring sub-pixel areas, so that a color mixture problem occurs, thereby a color difference is generated since the final color of the light emitting device is affected. The research is conducted to target the above problem by inventor of the present application, a manufacturing method for a light emitting device is provided, as shown in FIG. 1, the manufacturing method includes the following steps: step S1, a mask plate having a plurality of hollow portions is disposed on a substrate; step S2: by solution method, ink is applied on a surface of the substrate after passing through the hollow portions; and step S3: the ink is dried on the surface of the substrate to form a light emitting layer or a functional layer.

The inventor of the application further provides a manufacturing method for a light emitting device, the manufacturing method further includes the following steps: step S1, a mask plate having a plurality of hollow portions is disposed on a substrate; step S2: by solution method, ink is applied on a surface of the substrate after passing through the hollow portions; and step S3: the ink is solidified on the surface of the substrate to form a light emitting layer or a functional layer.

According to the above manufacturing method of the disclosure, the mask plate with multiple hollow portions is disposed on the substrate, and the hollow portions correspond to a target area of the substrate, a non-target area of the substrate may correspond to the hollow portions of the mask plate or correspond to a non-hollow portions of the mask plate, ink is applied on the surface of the substrate after passing through the hollow portion by solution method, and the ink on the surface of the substrate is dried or solidified, so as to form a light emitting layer or a functional layer, the mask plate is used for preventing the ink from being dispersed to other color areas, especially preventing the quantum dot ink from being diffused to other neighboring areas, the color mixture problem is effectively avoided, and the color precision of the light emitting device is improved.

The above solution method is selected from one or more combinations of inkjet printing, silk-screen printing, spin-coating, slit-coating and spray-coating, the above ink may include a glue-like substance with a large viscosity, or substance with a small viscosity, preferably the viscosity of the above ink is 50 cps or less.

Exemplary implementation modes of the manufacturing method for the light emitting device provided according to the disclosure is described in more details below, these exemplary implementation modes may be implemented in multiple different modes, and are not ought to be explained to be only limited to the implementation modes described herein. It is to be understood that these implementation modes are provided for completely and integrally disclosing the application, and the conception of these implementation modes are adequately delivered to persons of ordinary skill in the art.

The ink in the application may be any one of hole injection material ink, hole transporting material ink, electron injection material ink, and electrode material ink or electron transporting material ink, in the step S3, the ink is dried, so as to form a corresponding a hole injection layer, a hole transporting layer, an electron injection layer, an electrode layer or an electron transporting layer; and the ink in the application may be quantum dot material ink or organic light emitting material ink, in the step S3, the ink is dried or solidified, so as to form a corresponding quantum dot light emitting layer or an organic light emitting layer. In addition, in order to make the light emitting device have multiple colors of emitting light, preferably the quantum dots in the above quantum dot material ink is independently selected from any one or more types of red quantum dots, blue quantum dots and green quantum dots.

When the above ink is the quantum dot material ink, after the step S3 is executed, the manufacturing method further includes a process of at least one time of repeatedly performing the step S1 to the step S3, in each time of the repeated process, the hollow portions of the used mask plate correspond to the different areas of the substrate, the light emitting colors of the used inks are different. By disposing different light emitting colors of the quantum dot material inks on the target area of the substrate and drying or solidifying, the final light emitting color of the light emitting device is adjusted; and by disposing the red quantum dots, the blue quantum dots and the green quantum dots on the different positions of the substrate surface, RGB full-color display can be realized.

In addition, according to the different material types, the above ink may be classified as hydrophilic ink and hydrophobic ink. When the above quantum dot material ink is the hydrophilic ink, the above hydrophilic ink includes hydrophilic quantum dots, and the hydrophilic quantum dots are quantum dots of which surface ligands contain hydrophilic groups, preferably the hydrophilic group is carboxyl, amine, hydroxyl or sulfydryl; when the above quantum dot material ink is the hydrophobic ink, the above hydrophobic ink includes hydrophobic quantum dots, and the hydrophobic quantum dots are quantum dots of which surface ligands contain hydrophobic groups, preferably the hydrophobic group is hydrocarbon chain or ester group.

The above quantum dot material ink with hydrophilicity or hydrophobicity may also include curable resin or monomer(s) thereof and a solvent (or named as a dispersing agent). The solvent may be selected from long chain hydrocarbon of which boiling point is between 40 and 250 DEG C., a mixture of alcohol, ester and ether as organic solvent. Preferably, the hydrocarbon is a straight chain or branched chain alkane, for example, the hydrocarbon is C6-10 alkane. The organic solvent may be chlorobenzene, orthodichlorobenzene, tetrahydrofuran, anisole, morpholine, methylbenzene, ortho-xylene, m-xylene, p-xylene, alkylbenzene, nitrobenzene, normal hexane, cyclohexane, n-heptane, cycloheptane, dioxane, dichloromethane, trichloromethane, dichloroethane, chloroform, chlorobenzene, 1,4-dioxahexane, 1,2-dichloroethane, 1,1,1-trichloroethane, 1,1,2,2-tetrachloroethane, tetrahydronaphthalene, decalin, N, N-dimethylformamide, N, N-dimethylacetamide, dimethyl sulfoxide chloroform, tetrahydrofuran, dichloromethane, methylbenzene, normal hexane, methyl alcohol, ethyl alcohol, propyl alcohol, butyl alcohol, acetone, dioxane, dimethylformamide and dimethyl sulfoxide. The curable resin is selected from epoxy resin, acrylic resin, organic silicon resin, or the curable resin formed by crosslinking corresponding monomer(s). The above hydrophilic and hydrophobic quantum dot inks may further include double bonded crosslinking agent, photo initiator or heat initiator or the like.

In a preferable implementation mode, the mask plate in the step S1 has a modified surface, the modified surface includes a surface of the mask plate away from a substrate. The modified surface has hydrophilicity or hydrophobicity; the ink used in the step S2 and the modified surface have different hydrophilicity-hydrophobicity. By disposing the hydrophobic ink on the corresponding position of the substrate after the ink passing through the hollow portions of the mask plate with hydrophilic modified surface, or disposing the hydrophilic ink on the corresponding position of the substrate after the ink passing through the hollow portion of the mask plate with a hydrophobic modified surface, the ink may not adhere to the mask plate, so the material orientation is improved, thereby the spray-coating process of the solution method may be used for manufacturing the pixels, and inkjet printing device in lower precision may be used for manufacturing the pixels, thus the cost is reduced compared to using a precision inkjet printing device.

In the above preferable implementation mode, in order to further improve the material orientation by the mask plate, more preferably, the modified surface further includes a surface of the mask plate adjacent to the substrate. By making one side of the mask plate adjacent to the substrate have the modified surface, and the modified surface and the ink have the different hydrophilicity-hydrophobicity, the ink with hydrophilicity or hydrophobicity may not adhere to the surface adjacent to the substrate when passing through the hollow portions.

In the prior art, a metal material or other hydrophilic ultraviolet-aging resistant materials are used for preparing the mask plate generally. Because an oxidation layer on the metal surface has affinity with water, so the surfaces of most of metals are hydrophilic, the hydrophobic ink may be disposed on the corresponding position on the substrate after passing through the hollow portions of the above mask plate, and may not adhere to the surface modified mask plate, thereby the orientation of the hydrophobic material is improved.

In order to acquire the mask plate with hydrophobic modified surface, preferably, the above manufacturing method further includes a process of forming the modified surface: step S01, the mask plate is immerged in solution with a hydrophobic material, so that the hydrophobic material is fixed on the surface of the mask plate; and step S02, the mask plate fixed with the hydrophobic material is separated from the solution, and drying treatment or solidifying treatment is performed on the mask plate, so as to form the modified surface with hydrophobicity. Through the above preferable implementation mode, the hydrophilic ink may be disposed on the corresponding position on the substrate after passing through the hollow portions of the above mask plate, and may not adhere to the surface modified mask plate, thereby the orientation of the hydrophilic material is improved. In order to make the prepared mask plate with better hydrophobicity, preferably the hydrophobic material is a fluoric silane coupling agent.

In addition, in order to adequately use the hydrophilicity of the mask plate, preferably, the process of forming the modified surface includes the following steps: ultraviolet ozone photolysis oxidization is performed on the surface of the mask plate, so as to form the modified surface with hydrophilicity. By performing the ultraviolet ozone photolysis oxidization on the surface of the mask plate, various greasy stain and chemical substances remained on the surface of the mask plate are removed and the hydrophilic metal surface can be exposed, in the above optional embodiment, the hydrophobic fluoric silane coupling agent is removed and the hydrophilic metal surface is exposed, then the mask plate with the hydrophilic modified surface is obtained. Technical conditions of the above ultraviolet ozone photolysis oxidization may be set by those skilled in the art according to the prior art.

Because the mask plate with the modified surface is adopted or the surface of the mask plate is completely exposed, spray-coating process or inkjet printing process may be used in the above step S2 so that the ink is disposed on the surface of the substrate after passing through the hollow portions. Preferably the viscosity of the above hydrophilic ink or the hydrophobic ink is less than or equal to 50 cps, guaranteeing that the ink supply be controlled well by device's nozzles; and in order to guarantee that the ink being effectively atomized by the nozzles, preferably, the above spray-coating process is ultrasonic spray-coating, in order to improve the spray-coating effect of the preferable hydrophilic ink or the hydrophobic ink, the ultrasonic frequency used by the preferable ultrasonic spray-coating is 45-180 kHz, the viscosity of the preferable hydrophilic ink or hydrophobic ink is less than or equal to 10 cps.

In a preferable implementation mode, the substrate in the step S1 is provided with a pixel separating structure, and the pixel separating structure is provided with multiple mutually separated sub-pixel areas, and the hollow portions are disposed corresponding to each sub-pixel area; in the step S2, the ink enters the corresponding sub-pixel area after passing through the hollow portion. The above pixel separating structure may effectively prevent the ink color mixture between the different sub-pixel areas, thus the color accuracy is improved.

In order to reduce the effect of the color accuracy, i.e. deviation of quantity or position of the ink falling into the corresponding sub-pixel area caused by the deformation of the mask plate during the large area light emitting device preparation, the above mask plate may contact with the substrate surface of the side having the pixel separating structure; in addition, in order to make the hydrophilic ink or the hydrophobic ink more accurately enter the sub-pixel area of the pixel separating structure after passing through the hollow portions of the mask plate, preferably, the area of the above hollow portion is less than or equal to the area of the corresponding sub-pixel area, more preferably, the shape of the hollow portion is the same as the shape of the corresponding sub-pixel area.

More preferably, a naked surface of the pixel separating structure includes a hydrophilic surface or a hydrophobic surface. When the above naked surface of the pixel separating structure is the hydrophilic surface, in the step S2, the hydrophobic ink is disposed on the surface of the substrate after passing through the hollow portions; when the above naked surface of the pixel separating structure is the hydrophobic surface, in the step S2, the hydrophilic ink is disposed on the surface of the substrate after passing through the hollow portions, in the step of forming a light emitting layer or a functional layer, since the surface of the above pixel separating structure and the ink have different hydrophilicity-hydrophobicity, the ink may not remain on the upper surface or the side walls of the pixel separating structure, and may flow back to the pixel area under the effect of gravity, so the color mixture between the neighboring pixel areas is effectively prevented.

When the above manufacturing method of the disclosure is used for manufacturing the photoluminescence device, in another preferable implementation mode, the surface of the substrate in the step S1 has hydrophilic areas and hydrophobic areas, the hollow portions are disposed corresponding to the hydrophilic areas or the hydrophobic areas; in the step S2, the hydrophobic ink enters the hydrophobic area after passing through the hollow portion, or the hydrophilic ink enters the hydrophilic area after passing through the hollow portion. The above hydrophilic areas and hydrophobic areas may form multiple separated sub-pixel areas on the surface of a light transmitting substrate, when the hydrophilic quantum dot ink enters the hydrophilic areas, then the hydrophobic areas are used as a separating structure, or when the hydrophobic quantum dot ink enters the hydrophobic areas, then the hydrophilic areas are used as the separating structure, so that the quantum dot ink color mixture between the different sub-pixel areas is effectively prevented, and the color accuracy is improved; in addition, compared with manufacturing method which disposing the pixel separating structure on a transparent substrate, the above preferable implementation mode is capable of making the ink enter the desired sub-pixel area as well, and also reducing the manufacturing cost of the photoluminescence device.

More preferably, the surface of the substrate forms multiple hydrophilic areas and multiple hydrophobic areas, and each hydrophilic area and each hydrophobic area are alternately arranged. The above preferable implementation mode can form multiple mutually separated sub-pixel areas on the surface on the light transmitting substrate as well, the different colors of the quantum dot inks enter the different sub-pixel areas, so the above quantum dots may form a light emitting array with the irradiation of blue backlight, thereby the manufactured photoluminescence device realizes RGB full-color display.

In the above preferable implementation mode, in order to make the hydrophilic ink or the hydrophobic ink more accurately enter the hydrophilic or hydrophobic sub-pixel areas of the substrate through the hollow portions of the mask plate, more preferably, the area of the hollow portion of the mask plate is less than or equal to the area of the corresponding hydrophilic area or the hydrophobic area; the shape of the hollow portion of the mask plate is the same as the shape of the corresponding hydrophilic area or hydrophobic area.

The above preparation method for the substrate with the hydrophilic areas and the hydrophobic areas may include the following steps: step S001, the surface of the light transmitting substrate is provided with a raw material including a first reaction raw material; step S002, the first reaction raw material positioned in a first area is covered, and ultraviolet irradiation is performed on the first reaction raw material positioned in a second area, the first reaction raw material forms a second shielding area in the second area; step S003, the first reaction raw material in the first area is removed, the first area and the second shielding area are provided with a second reaction raw material; step S004, the second reaction raw material positioned in the second shielding area is covered, and the ultraviolet irradiation is performed on the second reaction raw material positioned in the first area, the second reaction raw material positioned forms a first shielding area in the first area, and the second reaction raw material on the second shielding area is removed, the first reaction raw material and the second reaction raw material are respectively selected from one of a hydrophilic reactant and a hydrophobic reactant, and the hydrophobicity-hydrophilicity of two reactants are opposite, the first shielding area and the second shielding area correspond to the hydrophilic area and the hydrophobic area.

In the above preparation method for the substrate, the above raw material including the first reaction raw material may further include solvent, coupling agent and initiator. The above step S001 includes the following steps: A, the coupling agent and the initiator are mixed in the solvent to form substrate treating solution; B, the surface of at least one side of the substrate is placed in the substrate treating solution, the coupling agent is bonding and fixing on the surface of the light transmitting substrate and then a bonded surface is formed; and C, the first reaction raw material is disposed on the bonded surface. In the above step S002, by performing ultraviolet irradiation on the first reaction raw material positioned in the second area, a grafting reaction occurs between the first reaction raw material and the coupling agent under the ultraviolet irradiation, then the above second shielding area is formed; and in the above step S004, by performing the ultraviolet irradiation on the second reaction raw material positioned in the first area, the grafting reaction occurs between the second reaction raw material and the coupling agent under the ultraviolet irradiation, then the above first shielding area is formed.

In the above preparation method for the substrate, a process of removing the first reaction raw material in the first area may include the following steps: the first reaction raw material in the first area is washed by using a solvent, and the surface of the substrate is dried or solidified; in the same way, a process of removing the second reaction raw material in the second area may include the following steps: the second reaction raw material in the second shielding area is washed by using the solvent, and the surface of the substrate is dried or solidified. Those skilled in the art may set the technical conditions of the above washing process and drying or solidifying treatment process according to the prior art.

In order to improve the grafting reaction between the first reaction raw material and the coupling agent and the grafting reaction between the second reaction raw material and the coupling agent, preferably, a general formula of the above coupling agent is (X₁—X₂—X₃—)Si—Y, where Y is vinyl group or Y is hydrocarbyl group of which the tail end having SH group, X₁, X₂ and X₃ are respectively and independently selected from any one of Cl, CH₃, OCH₃, OCH₂CH₃ and CH₂CH₃, and X₁, X₂ and X₃ are not hydrocarbyl groups at the same time; a general formula of the above first reaction raw material and second reaction raw material is A-B, when A is vinyl group, then Y is the hydrocarbyl group of which the tail end is provided with the SH group, or when A is hydrocarbyl group of which the tail end is provided with the SH group, then Y is the vinyl group, when B is residue with hydrophilic group, then the first reaction raw material or the second reaction raw material is hydrophilic reactant, preferably the hydrophilic group is any one or more of sulfonic acid group, amine group, hydroxyl group, carboxyl group and amino group, or when B is a residue with hydrophobic group, then the first reaction raw material or the second reaction raw material is hydrophobic reactant, preferably the hydrophilic group is any one or more of hydrocarbyl group, ester group, halogen and nitro group.

The above manufacturing method of the disclosure may be used for manufacturing any one or more layers of the light emitting layer or the functional layer of the electroluminescence device, the above substrate is a first electrode substrate, and when the light emitting layer is formed in the above step S3, preferably, after the step S3, the manufacturing method further includes the step S4: one side of the light emitting layer away from the first electrode substrate is provided with a second electrode. The above preferable implementation mode may be used for forming the electroluminescence device with the structure having first electrode substrate/light emitting layer/second electrode; when the functional layer is formed in the above step S3, preferably, after the step S3, the manufacturing method further includes the step S4: the functional layer is a first injection layer or a first transporting layer, one side of the first injection layer or the first transporting layer away from the first electrode substrate is provided with the light emitting layer, and one side of the light emitting layer away from the first electrode substrate is provided with the second electrode. The above preferable implementation mode may be used for forming the electroluminescence device with functional layer.

In the above preferable implementation mode, when the functional layer formed in the step S3 is the first injection layer, more preferably, in the step S4, the manufacturing method further includes the following steps: before a process of disposing the light emitting layer, the steps S1 to S3 are repeatedly performed, so the first transporting layer is disposed on the surface of the first injection layer; after the process of disposing the light emitting layer, the steps S1 to S3 are repeatedly performed, so a second transporting layer is disposed on the surface of the light emitting layer; and after the process of disposing the light emitting layer, the steps S1 to S3 are repeatedly performed, so an second injection layer is disposed on the surface of the second transporting layer. The above preferable implementation mode may be used for forming the electroluminescence device with structure having first electrode substrate/first injection layer/first transporting layer/light emitting layer/second transporting layer/second injection layer/second electrode.

In the above electroluminescence device, when the first electrode is an anode, and the second electrode is a cathode, the first injection layer is the hole injection layer, the first transporting layer is the hole transporting layer, the second injection layer is the electron injection layer, and the second transporting layer is the electron transporting layer; and while the first electrode is a cathode, and the second electrode is an anode, the first injection layer the electron injection layer, the first transporting layer is the electron transporting layer, the second injection layer is the hole injection layer, the second transporting layer is the hole transporting layer, so that an inverted electroluminescence device is formed.

It is to be noted that the preparation technology for each layer in the electroluminescence device is not limited to the above preferable implementation modes, those skilled in the art may prepare other layers of the electroluminescence device in combination with a conventional process in the prior art.

According to another aspect of the application, a light emitting device prepared by the above manufacturing method is further provided, the light emitting device is an electroluminescence device or a photoluminescence device. Because the above electroluminescence device and/or the above photoluminescence device is prepared by the above manufacturing method, and according to the manufacturing method, the mask plate with multiple hollow portions is disposed on the substrate, and the ink is disposed on the surface of the substrate after passing through the hollow portions by solution method, and the ink on the substrate surface is dried or solidified, so as to form the light emitting layer or the functional layer, so that the mask plate is used for preventing the ink from being dispersed to other color areas, a color mixture problem is effectively avoided, and the color precision of the light emitting device with the electroluminescence device and/or the photoluminescence device is improved.

According to yet another aspect of the application, a hybrid light emitting device is further provided, the hybrid light emitting device includes an electroluminescence device and a photoluminescence device disposed at the light emitting side of the electroluminescence device, the electroluminescence device and/or the photoluminescence device is prepared by the above manufacturing method. Because the electroluminescence device and/or the photoluminescence device in the above hybrid light emitting device is prepared by the manufacturing method for the light emitting device, according to the manufacturing method, the mask plate with multiple hollow portions is disposed on the substrate, and the ink is disposed on the surface of the substrate after passing through the hollow portions by solution method, and the ink on the substrate surface is dried or solidified, so as to form the light emitting layer or the functional layer, so that the mask plate is used for preventing the ink from being dispersed to other color areas, the color mixture problem is effectively avoided, and the color precision of the hybrid light emitting device with the electroluminescence device and/or the photoluminescence device is improved.

According to another aspect of the application, another surface modified mask plate is further provided, as shown in FIG. 2, the surface modified mask plate is provided with multiple hollow portions 10, the surface modified mask plate is provided with a modified surface 20, the modified surface 20 includes a first modified surface 210 and a second modified surface 220, the first modified surface 210 is disposed around the hollow portions 10, the modified surface 20 except the first modified surface 210 is the second modified surface 220, and the first modified surface 210 and the second modified surface 220 are respectively a hydrophilic surface and a hydrophobic surface.

Because the surface modified mask plate is provided with the modified surface, the modified surface includes the first modified surface and the second modified surface, the first modified surface is disposed around the hollow portions, the modified surface except the first modified surface is the second modified surface, and the first modified surface and the second modified surface are respectively the hydrophilic surface and the hydrophobic surface, when the above surface modified mask plate is used for preparing a light emitting device, the hydrophilic or hydrophobic ink enters the corresponding sub-pixel area after passing through the hollow portion surrounded by the hydrophobic surface, or the hydrophilic ink enters the corresponding sub-pixel area after passing through the hollow portion surrounded by the hydrophilic surface, and the ink may not adhere to the surface modified mask plate, the material orientation is improved by using the mask plate, thereby the spray-coating process of the solution method may be used for manufacturing the pixels, and inkjet printing device with lower precision may be used for manufacturing the pixels, the required cost is reduced finally compare to the cost of using a precision inkjet printing device.

According to another aspect of the application, a surface modifying method for a mask plate is further provided, the obtained surface modified mask plate is as shown in FIG. 2, the surface modifying method includes the following steps: the surface of the mask plate with multiple hollow portions 10 is provided with a modified surface 20, the modified surface 20 includes a first modified surface 210 and a second modified surface 220, the first modified surface 210 is disposed around the hollow portions 10, the modified surface 20 except the first modified surface 210 is the second modified surface 220, and the first modified surface 210 and the second modified surface 220 are respectively a hydrophilic surface and a hydrophobic surface.

In the above surface modifying method for the mask plate, because the surface of the mask plate is provided with the modified surface, the modified surface includes the first modified surface 210 and the second modified surface 220, the first modified surface is disposed around the hollow portions 10, the modified surface except the first modified surface 210 is the second modified surface 220, and the first modified surface 210 and the second modified surface 220 are respectively the hydrophilic surface and the hydrophobic surface, so when the above surface modified mask plate is used for preparing a quantum dot film layer, the hydrophobic ink enters the corresponding sub-pixel area after passing through the hollow portion 10 surrounded by the hydrophobic surface, or the hydrophilic ink enters the corresponding sub-pixel area after passing through the hollow portion surrounded by the hydrophilic surface, and the ink may not adhere to the surface modified mask plate, the nonuniform ink quantity entering each sub-pixel area caused by the ink adhesion to the mask plate is effectively prevented, thereby the color accuracy reduction caused by the ununiform ink quantity in each sub-pixel area is effectively prevented.

The above mask plate is made of a metal material generally, because an oxidation layer on the metal surface has affinity with water, so the surfaces of most of metals are hydrophilic, the preferable material herein is a hydrophilic metal material or other hydrophilic ultraviolet-aging resistant materials. In a preferable implementation mode, the above step of disposing the modified surface 20 on the surface of the mask plate includes the following steps: step S01′, the mask plate is immerged in solution with a hydrophobic material, so that the hydrophobic material is fixed on the surface of the mask plate, preferably the hydrophobic material is a fluoric silane coupling agent; and step S02′, the mask plate fixed with the hydrophobic material is separated from the solution, and drying treatment or solidifying treatment is performed on the mask plate; and step S03′, a first photomask is disposed on the first surface of the mask plate, the first photomask is formed by multiple first shielding portions and a first light transmitting portion connected to each first shielding portion, the first shielding portions correspond to the hollow portions 10 in a one-to-one way, and the area of each first shielding portion is greater than the area of each hollow portion 10 corresponding to the first shielding portion, ultraviolet ozone photolysis oxidization is performed on the first surface of the mask plate with the first photomask, and the ultraviolet ozone photolysis oxidization is performed on the second surface of the mask plate opposite to the first surface, so as to form a second modified surface 220 with hydrophilicity, the rest surface of the mask plate forms a first modified surface 210 with hydrophobicity; or a second photomask is disposed on the mask plate, the second photomask is formed by multiple second light transmitting portions and a second shielding portion connected to each second light transmitting portion, and the second light transmitting portions correspond to the hollow portions 10 in a one-to-one way, and the area of each second light transmitting portion is greater than the area of each hollow portion 10 corresponding to the second light transmitting portion, the ultraviolet ozone photolysis oxidization is performed on the mask plate, so that the surface of the mask plate corresponding to the second light transmitting portions forms the first modified surface 210 with hydrophilicity, and the rest surface of the mask plate forms the second modified surface 220 with hydrophobicity.

In the above step of disposing the modified surface 20, in order to make the prepared surface modified mask plate with better hydrophobicity, preferably the hydrophobic material is a fluoric silane coupling agent. By performing the ultraviolet ozone photolysis oxidization on the hydrophobic material, the hydrophobic fluoric silane coupling agent is removed and the hydrophilic metal surface is exposed, process conditions of the above ultraviolet ozone photolysis oxidization may be set by those skilled in the art according to the prior art.

According to another aspect of the application, a manufacturing method for an electroluminescence device is further provided, as shown in FIG. 3, the manufacturing method includes the following steps: step S1′, a first electrode substrate with a pixel separating structure is provided, the pixel separating structure is provided with multiple mutually separated sub-pixel areas; step S2′, the above surface modified mask plate is disposed on one side of the first electrode substrate provided with the pixel separating structure, the first modified surface of the surface modified mask plate is disposed away from the first electrode substrate, and one or more hollow portions of the surface modified mask plate are disposed corresponding to each sub-pixel area of at least partial sub-pixel areas; step S3′, by solution method, the ink having the same hydrophobicity-hydrophilicity as the first modified surface of the surface modified mask plate enters the corresponding sub-pixel area after passing through the hollow portion; and step S4′, the ink in the sub-pixel area is dried or solidified, so as to form a light emitting layer or a functional layer.

According to another aspect of the application, a manufacturing method for an electroluminescence device is further provided, the manufacturing method includes the following steps: step S1′, a first electrode substrate with a pixel separating structure is provided, the pixel separating structure is provided with multiple mutually separated sub-pixel areas; step S2′, the above surface modified mask plate is disposed on one side of the first electrode substrate having the pixel separating structure, the first modified surface of the surface modified mask plate is disposed away from the first electrode substrate, and one or more hollow portions of the surface modified mask plate are disposed corresponding to each sub-pixel area of at least partial sub-pixel areas; step S3′, by solution method, the ink having the same hydrophobicity-hydrophilicity as the first modified surface of the surface modified mask plate enters the corresponding sub-pixel area after passing through the hollow portion; and step S4′, the ink in the sub-pixel area is dried or solidified, so as to form a light emitting layer or a functional layer.

In the manufacturing method of the disclosure, because the first electrode substrate with the pixel separating structure is provided, the pixel separating structure is provided with multiple mutually separated sub-pixel areas, the modified mask plate is disposed at one side of the first electrode substrate having pixel separating structure, the above surface modified mask plate is provided with the modified surface, the modified surface includes the first modified surface and the second modified surface, the first modified surface is disposed around the hollow portions, the modified surface except the first modified surface is the second modified surface, and the first modified surface and the second modified surface are respectively the hydrophilic surface and the hydrophobic surface, so the material orientation is improved through the combination of the above pixel separating structure and the mask plate, thereby the spray-coating process of solution method may be used for manufacturing the pixels, and an inkjet printing device in lower precision may be used for manufacturing the pixels, the required cost is reduced finally compare to the cost of using a precision inkjet printing device.

The above surface modified mask plate is as shown in FIG. 2, exemplary implementation modes of the manufacturing method for the electroluminescence device provided according to the disclosure is described in more details below in combination with FIG. 2. However, these exemplary implementation modes may be implemented in multiple different modes, and are not ought to be explained to be only limited to the implementation modes described herein. It is to be understood that these implementation modes are provided for completely and integrally disclosing the application, and the conception of these implementation modes are adequately delivered to those persons of ordinary skill in the art.

Firstly, the step S1′ is executed: the first electrode substrate with the pixel separating structure is provided, the pixel separating structure is provided with multiple mutually separated sub-pixel areas. The above pixel separating structure is used for preventing the ink color mixture between the different sub-pixel areas. More preferably, the naked surface of the pixel separating structure includes the hydrophilic surface or the hydrophobic surface. By making the surface of the above pixel separating structure and the ink have different hydrophilicity-hydrophobicity, in the step of forming a light emitting layer or a functional layer, the ink may not remain on the upper surface or the side wall of the pixel separating structure, and may flow back to the pixel area under the effect of gravity, so the color mixture between the neighboring pixel areas is effectively prevented, and the color accuracy is improved.

After the step S1′ is executed, the S2′ is executed: the above surface modified mask plate is disposed on one side of the first electrode substrate provided with the pixel separating structure, the modified surface 20 of the surface modified mask plate is positioned at one side of the surface modified mask plate away from the first electrode substrate, and one or more hollow portions of the surface modified mask plate are disposed corresponding to each sub-pixel area of at least partial sub-pixel areas. In order to reduce the effect of the color accuracy, i.e. deviation of quantity or position of the ink falling into the corresponding sub-pixel area caused by the mask plate deformation during the large area the light emitting device preparation, the above mask plate may contact with the side of substrate surface having the pixel separating structure; in addition, in order to make the hydrophilic ink or the hydrophobic ink more accurately enter the sub-pixel areas of the pixel separating structure after passing through the hollow portions of the mask plate, preferably, the area of the above hollow portion is less than or equal to the area of the corresponding sub-pixel area, more preferably, the shape of the hollow portion is the same as the shape of the corresponding sub-pixel area.

After the step S2′ is executed, the step S3′ is executed: by solution method, the ink having the same hydrophobicity-hydrophilicity as the first modified surface 210 of the surface modified mask plate enters the corresponding sub-pixel area after passing through the hollow portion. By using the surface modified mask plate, the above solution method may be a spray-coating process or a low-precision inkjet printing process, thereby the spray-coating process or the inkjet printing process is used to enable the hydrophilic ink or the hydrophobic ink to enter the sub-pixel area after passing through the hollow portion. Preferably the viscosity of the above hydrophilic ink or the hydrophobic ink is less than or equal to 50 cps, guaranteeing that the ink supply be controlled well by device's nozzles; and in order to guarantee that the ink being effectively atomized by the nozzles, preferably, the above spray-coating process is ultrasonic spray-coating, in order to improve the spray-coating effect of the preferable hydrophilic ink or the hydrophobic ink, the ultrasonic frequency used by the preferable ultrasonic spray-coating is 45-180 kHz, the viscosity of the preferable hydrophilic ink or hydrophobic ink is less than or equal to 10 cps.

The above ink may be any one of hole injection material ink, hole transporting material ink, electron injection material ink and electron transporting layer material ink, or may be any one of quantum dot material ink and organic light emitting material ink, by making the different types of inks enter the corresponding sub-pixel areas, a light emitting layer or different types of functional layers are formed in the subsequent step S4′; in addition, the ink includes the hydrophilic ink and the hydrophobic ink, when the hydrophilic ink or the hydrophobic ink is the quantum dot material ink, the above hydrophilic ink includes hydrophilic quantum dots, and the hydrophilic quantum dots are quantum dots of which surface ligands contain hydrophilic groups, preferably the hydrophilic group is carboxyl group, amine group, hydroxyl group or sulfydryl group; when the above quantum dot material ink is the hydrophobic ink, the above hydrophobic ink includes hydrophobic quantum dots, and the hydrophobic quantum dots are quantum dots of which surface ligands contain hydrophobic groups, preferably the hydrophobic group is hydrocarbon chain or ester group. To enable the electroluminescence device to emit light of different colors, preferably the above hydrophilic quantum dots and the above hydrophobic quantum dots are independently selected from any one of red quantum dots, blue quantum dots and green quantum dots.

When the naked surface of the pixel separating structure in the above step S1′ is hydrophilic surface, in the step S3′, in the step of enabling the hydrophobic ink to enter the sub-pixel area after passing through the hollow portion; and when the naked surface of the pixel separating structure is hydrophobic surface, in the step S3′, in the step of enabling the hydrophilic ink to enter the sub-pixel area after passing through the hollow portion. The above pixel separating structure with the hydrophilic/hydrophobic naked surface enables the hydrophilic ink or the hydrophobic ink to flow back to the pixel area under the effect of gravity, and not remain on the upper surface or the side walls of the pixel separating structure, thereby the color mixture between the neighboring pixel areas is effectively prevented.

After the step S3′ is executed, the S4′ is executed: the ink in the sub-pixel areas is dried or solidified, so as to form a light emitting layer or a functional layer. The above ink drying process conditions may be set by persons skilled in the art according to the prior art; in addition, when the above ink is the hole injection material ink, the hole transporting material ink, the electron injection material ink or the electron transporting layer material ink, in the step S4′, the ink is dried or solidified, so as to correspondingly form the hole injection layer, the hole transporting layer, the electron injection layer or the electron transporting layer; and when the above ink is the quantum dot material ink or the organic light emitting material ink, in the step S4′, the ink is dried or solidified, so as to form the corresponding quantum dot light emitting layer or the organic light emitting layer.

When the above ink is the quantum dot material ink, in a preferable implementation mode, the manufacturing further includes a process of at least one time of repeatedly performing the step S2′ to the step S4′, in each time of the repeated process, the hollow portions of the used surface modified mask plate correspond to the different sub-pixel areas, the light emitting colors of the used inks are different, the inks of the different sub-pixel areas are different in light emitting colors, the used quantum dot inks may be the hydrophilic ink or the hydrophobic ink, in the above preferable implementation mode, by disposing the different light emitting colors of the hydrophilic inks or the hydrophobic inks in every sub-pixel area and drying or solidifying, the full-color display of the electroluminescence device can be realized; in addition, by respectively disposing the red quantum dots, the blue quantum dots and the green quantum dots in the different sub-pixel areas, the electroluminescence device may achieve the wider display color gamut.

When the light emitting layer is formed in the step S4′, preferably, after the step S4′, the manufacturing further includes a step S5′: one side of the light emitting layer away from the first electrode substrate is provided with a second electrode. The above preferable implementation mode may be used for forming the electroluminescence device with the structure having first electrode substrate/light emitting layer/second electrode; when the functional layer is formed in the above step S4′, preferably, after the step S4′, the manufacturing method further includes the step S5′: when the functional layer is formed in the step S4′, the functional layer is a first injection layer or a first transporting layer, one side of the first injection layer or the first transporting layer away from the first electrode substrate is provided with the light emitting layer, and one side of the light emitting layer away from the first electrode substrate is provided with the second electrode. The above preferable implementation mode may be used for forming the electroluminescence device with the functional layer.

When the functional layer formed in the S4′ is the first injection layer, in a preferable implementation mode, in the step S5′, the manufacturing method further includes the following steps: before a process of disposing the light emitting layer, the steps S2′ to S4′ are repeatedly performed, so a first transporting layer is disposed on the surface of the first injection layer; after the process of disposing the light emitting layer, the steps S2′ to S4′ are repeatedly performed, a second transporting layer is disposed on the surface of the light emitting layer; and after the process of disposing the light emitting layer, the steps S2′ to S4′ are repeatedly performed, a second injection layer is disposed on the second transporting layer. The above preferable implementation mode may be used for forming the electroluminescence device with the structure having first electrode substrate/first injection layer/first transporting layer/light emitting layer/second transporting layer/second injection layer/second electrode. In the above electroluminescence device, when the first electrode is an anode, and the second electrode is a cathode, the first injection layer is a hole injection layer, the first transporting layer is a hole transporting layer, the second injection layer is an electron injection layer, and the second transporting layer is an electron transporting layer; and when the first electrode is the cathode, and the second electrode is the anode, the first injection layer the electron injection layer, the first transporting layer is the electron transporting layer, the second injection layer is the hole injection layer, the second transporting layer is the hole transporting layer, so that an inverted electroluminescence device is formed.

It is to be noted that the preparation process for each layer in the electroluminescence device is not limited to the above preferable implementation modes, the above manufacturing method of the disclosure may be used for manufacturing any one or more layers in the light emitting layer or the functional layer of the electroluminescence device, and other layers of the electroluminescence device may be prepared by those skilled in the art in combination with a conventional process in the prior art.

According to another aspect of the disclosure, a manufacturing method for a quantum dot film is further provided, as shown in FIG. 5, the manufacturing method for the quantum dot film includes the following steps: step a, hydrophilic areas and hydrophobic areas are formed on a first surface of a light transmitting substrate; step b, the surface modified mask plate with multiple hollow portions are disposed on the first surface of the light transmitting substrate, and the hollow portions of the surface modified mask plate are disposed corresponding to the hydrophilic areas or the hydrophobic areas, the surface modified mask plate is provided with a modified surface, the modified surface includes a first modified surface and a second modified surface, the first modified surface is disposed around the hollow portions, the modified surface except the first modified surface is the second modified surface, and the first modified surface and the second modified surface are different and are respectively selected from one of hydrophilic surface and hydrophobic surface, and the first modified surface is positioned at one side away from the first surface of the light transmitting substrate of the surface modified mask plate; step c, the first modified surface is the hydrophobic surface, so the hydrophobic quantum dot ink enters the hydrophobic area after passing through the hollow portion, or the first modified surface is the hydrophilic surface, so the hydrophilic quantum dot ink enters the hydrophilic area after passing through the hollow portion; and step d, the quantum dot ink in the hydrophilic area or the hydrophobic area is dried.

The above light transmitting substrate may transmit light with wavelength between 400 nm and 700 nm, a whole light transmittance of the light transmitting substrate is more than 50%, and the preferable light transmittance is more than 90%.

According to another aspect of the disclosure, a manufacturing method for a quantum dot film is further provided, the manufacturing method for the quantum dot film includes the following steps: step a, hydrophilic areas and hydrophobic areas are formed on a first surface of a light transmitting substrate; step b, the surface modified mask plate with multiple hollow portions are disposed on the first surface of the light transmitting substrate, and the hollow portions of the surface modified mask plate are disposed corresponding to the hydrophilic areas or the hydrophobic areas, the surface modified mask plate is provided with a modified surface, the modified surface includes a first modified surface and a second modified surface, the first modified surface is disposed around the hollow portions, the modified surface except the first modified surface is the second modified surface, and the first modified surface and the second modified surface are different and are respectively selected from one of a hydrophilic surface and a hydrophobic surface, and the first modified surface is positioned at one side of the surface modified mask plate away from the first surface of the light transmitting substrate; step c, the first modified surface is the hydrophobic surface, so the hydrophobic quantum dot material ink enters the hydrophobic area after passing through the hollow portion, or the first modified surface is the hydrophilic surface, the hydrophilic quantum dot material ink enters the hydrophilic area after passing through the hollow portion; and step d, the quantum dot material ink in the hydrophilic area or the hydrophobic area is solidified.

In the above manufacturing method for the quantum dot film of the disclosure, because the hydrophilic areas and the hydrophobic areas are formed on the first surface of the light transmitting substrate, and the surface modified mask plate is disposed on the first surface of the light transmitting substrate, the hollow portions are disposed corresponding to the hydrophilic areas or the hydrophobic areas, the different quantum dot ink enters the different pixel areas after passing through the surface modified mask plate, and multiple separated sub-pixel areas are formed on the surface of the light transmitting substrate by the hydrophilic areas and the hydrophobic areas on the light transmitting substrate, the hydrophilic quantum dot ink is enabled to enter the hydrophilic areas, the hydrophobic areas are used as a separating structure, or the hydrophobic quantum dot ink enters the hydrophobic areas, and the hydrophilic areas are used as the separating structure, so that the quantum dot ink color mixture between the different sub-pixel areas is effectively prevented, thereby a problem that the color accuracy is reduced because of the quantum dot ink color mixture in the different sub-pixel areas is effectively solved; in addition, compared with manufacturing method of disposing the pixel separating structure on a transparent substrate, the above manufacturing method of the application enables the ink to enter the desired sub-pixel area as well, and to reduce the manufacturing cost of the photoluminescence device.

Exemplary implementation modes of the manufacturing method for the quantum dot film provided according to the disclosure is described in more detail below, however, these exemplary implementation modes may be implemented in multiple different modes, and are not ought to be explained to be only limited to the implementation modes described herein. It is to be understood that these implementation modes are provided for completely and integrally disclosing the application, and the conception of these implementation modes are adequately delivered to persons of ordinary skill in the art.

Firstly, the step a is executed: the hydrophilic areas and the hydrophobic areas are formed on the first surface of the light transmitting substrate. In a preferable implementation mode, first surface forms multiple hydrophilic areas and multiple hydrophobic areas, and each hydrophilic area and each hydrophobic area are alternately arranged. The above preferable implementation mode may be used for forming multiple mutually separated sub-pixel areas on the first surface of the light transmitting substrate, so quantum dot inks having different colors enter different sub-pixel areas, and a film with the quantum dots may form a light emitting array under the irradiation of blue backlight, thereby the prepared quantum dot color film can realize RGB full-color display.

In a preferable implementation mode, the step a includes the following steps: step S001, the surface of the light transmitting substrate is provided with a raw material including a first reaction raw material; step S002, the first reaction raw material positioned in a first area is covered, and ultraviolet irradiation is radiated on the first reaction raw material positioned in a second area, the first reaction raw material forms a second shielding area in the second area; step S003, the first reaction raw material in the first area is removed, the first area and the second shielding area are provided with a second reaction raw material; step S004, the second reaction raw material positioned in the second shielding area is covered, and the ultraviolet irradiation is radiated on the second reaction raw material positioned in the first area, the second reaction raw material positioned forms a first shielding area in the first area, and the second reaction raw material on the second shielding area is removed, the first reaction raw material and the second reaction raw material are respectively selected from one of hydrophilic reactant and hydrophobic reactant, and the hydrophobicity-hydrophilicity of the two reactants are opposite, the first shielding area and the second shielding area correspond to hydrophilic areas and hydrophobic areas.

In the above preferable implementation mode, the above raw material including the first reaction raw material may further include solvent, coupling agent and initiator. The above step S001 includes the following steps: A, the coupling agent and the initiator are mixed in the solvent, to form substrate treating solution; B, the surface of at least one side of the substrate is placed in the substrate treating solution, the coupling agent is bonding and fixing on the surface of the light transmitting substrate and a bonded surface is formed; and C, the first reaction raw material is disposed on the bonded surface. In the above step S002, by performing ultraviolet irradiation on the first reaction raw material positioned in the second area, a grafting reaction occurs between the first reaction raw material and the coupling agent under the ultraviolet irradiation, then the above second shielding area is formed; and in the above step S004, by performing the ultraviolet irradiation on the second reaction raw material positioned in the first area, the grafting reaction occurs between the second reaction raw material and the coupling agent under the ultraviolet irradiation, then the above first shielding area is formed.

In the above preferable implementation mode, a process of removing the first reaction raw material in the first area may include the following steps: the first reaction raw material in the first area is washed by using a solvent, and the surface of the substrate is dried or solidified; in the same way, a process of removing the second reaction raw material in the second area may include the following steps: the second reaction raw material in the second shielding area is washed by using the solvent, and the surface of the substrate is dried or solidified. Those skilled in the art may set the technical conditions of the above washing process and drying or solidifying treatment process according to the prior art.

In order to improve the grafting reaction between the first reaction raw material and the coupling agent and the grafting reaction between the second reaction raw material and the coupling agent, preferably, a general formula of the above coupling agent is (X₁—X₂—X₃—)Si—Y, where Y is vinyl group or Y is an hydrocarbyl group having SH group as the tail end, X₁, X₂ and X₃ are respectively and independently selected from any one of Cl, CH₃, OCH₃, OCH₂CH₃ and CH₂CH₃, and X₁, X₂ and X₃ are not the hydrocarbyl groups at the same time; a general formula of the above first reaction raw material and second reaction raw material is A-B, when A is vinyl group, then Y is hydrocarbyl group of which the tail end is provided with the SH group, or when A is hydrocarbyl group of which the tail end is provided with the SH group, then Y is the vinyl group, when B is residue with hydrophilic group, then the first reaction raw material or the second reaction raw material is a hydrophilic reactant, preferably the hydrophilic group is any one or more of sulfonic acid group, amine group, hydroxyl group, carboxyl group and amino group, or B is residue with hydrophobic group, then the first reaction raw material or the second reaction raw material is hydrophobic reactant, preferably the hydrophilic group is any one or more of hydrocarbyl group, ester group, halogen and nitro group.

After the step a is executed, the step b is executed: the above surface modified mask plate is disposed on the first surface of the light transmitting substrate, and the hollow portions 10 of the surface modified mask plate are disposed corresponding to the hydrophilic areas or the hydrophobic areas, the surface modified mask plate is provided with a modified surface 20, the modified surface 20 includes a first modified surface 210 and a second modified surface 220, the first modified surface 210 is disposed around the hollow portions 10, the modified surface 20 except the first modified surface 210 is the second modified surface 220, and the first modified surface 210 and the second modified surface 220 have the hydrophilicity and the hydrophobicity respectively, the above surface modified mask plate is as shown in FIG. 2. In order to make the hydrophilic ink or the hydrophobic ink more accurately enter the light transmitting substrate after passing through the hollow portions 10 of the surface modified mask plate in the subsequent step c, preferably, the area of the hollow portion 10 in the surface modified mask plate is less than or equal to the area of the corresponding hydrophilic area or the hydrophobic area, more preferably, the shape of the hollow portion 10 is the same as the shape of the corresponding hydrophilic area or the hydrophobic area.

In a preferable implementation mode, the above manufacturing method further includes a process of preparing the above surface modified mask plate: step S01, the mask plate is immerged in solution with a hydrophobic material, so that the hydrophobic material is fixed on the surface of the mask plate, preferably the hydrophobic material is a fluoric silane coupling agent; and step S02, the mask plate fixed with the hydrophobic material is separated from the solution, and drying treatment is performed on the mask plate; and S03, a first photomask is disposed on the first surface of the mask plate, the first photomask is formed with multiple first shielding portions and a first light transmitting portion connected to each first shielding portion, the first shielding portions correspond to the hollow portions 10 in a one-to-one way, and the area of each first shielding portion is greater than the area of each hollow portion 10 corresponding to the first shielding portion, ultraviolet ozone photolysis oxidization is performed on the first surface of the mask plate by the first photomask, and the ultraviolet ozone photolysis oxidization is performed on the second surface opposite to the first surface of the mask plate, so as to form a second modified surface 220 with hydrophilicity, the rest surface of the mask plate forms a first modified surface 210 with hydrophobicity; or a second photomask is disposed on the mask plate, the second photomask is formed with multiple second light transmitting portions and a second shielding portion connected to each second light transmitting portion, and the second light transmitting portions correspond to the hollow portions 10 in a one-to-one way, and the area of each second light transmitting portion is greater than the area of each hollow portion 10 corresponding to the second light transmitting portion, the ultraviolet ozone photolysis oxidization is performed on the mask plate, so that the surface corresponding to the second light transmitting portions of the mask plate forms the first modified surface 210 with hydrophilicity, and the rest surface of the mask plate forms the second modified surface 220 with hydrophobicity.

In another preferable implementation mode, the above manufacturing method further includes a process of preparing the above surface modified mask plate: step S01, the mask plate is immerged in solution with a hydrophobic material, so that the hydrophobic material is fixed on the surface of the mask plate, preferably the hydrophobic material is a fluoric silane coupling agent; and step S02, the mask plate fixed with the hydrophobic material is separated from the solution, and drying treatment is performed on the mask plate; and S03, the first photomask is disposed on the first surface of the mask plate, the first photomask is formed with multiple first shielding portions and a first light transmitting portion connected to each first shielding portion, the first shielding portions correspond to the hollow portions 10 in one-to-one way, and the area of each first shielding portion is greater than the area of each hollow portion 10 corresponding to the first shielding portion, ultraviolet ozone photolysis oxidization is performed on the first surface of the mask plate by the first photomask, and the ultraviolet ozone photolysis oxidization is performed on the second surface opposite to the first surface of the mask plate, so as to form a second modified surface 220 with hydrophilicity, the rest surface of the mask plate forms a first modified surface 210 with hydrophobicity; or a second photomask is disposed on the mask plate, the second photomask is formed with multiple second light transmitting portions and a second shielding portion connected to each second light transmitting portion, and the second light transmitting portions correspond to the hollow portions 10 in a one-to-one way, and the area of each second light transmitting portion is greater than the area of each hollow portion 10 corresponding to the second light transmitting portion, the ultraviolet ozone photolysis oxidization is performed on the mask plate, so that the surface corresponding to the second light transmitting portions of the mask plate forms the first modified surface 210 with hydrophilicity, and the rest surface of the mask plate forms the second modified surface 220 with hydrophobicity.

In the above step of preparing the surface modified mask plate, the mask plate is made of metal material generally, since oxidation layer on the metal surface has affinity with water, so the surfaces of most of metals are hydrophilic, the preferable material herein is hydrophilic metal material or other hydrophilic ultraviolet-aging resistant materials; in addition, in order to make the prepared surface modified mask plate has better hydrophobicity, preferably the hydrophobic material is a fluoric silane coupling agent. By performing the ultraviolet ozone photolysis oxidization on the hydrophobic material, the hydrophobic fluoric silane coupling agent is removed and the hydrophilic metal surface is exposed, technical conditions of the above ultraviolet ozone photolysis oxidization may be set by those skilled in the art according to the prior art.

After the step b is executed, the step c is executed: the first modified surface 210 is the hydrophobic surface, the hydrophobic quantum dot ink enters the hydrophobic area after passing through the hollow portion 10, or the first modified surface 210 is the hydrophilic surface, the hydrophilic quantum dot ink enters the hydrophilic area after passing through the hollow portion 10. A spray-coating process or an inkjet printing process may be used for enabling the quantum dot ink to enter the hydrophilic area or the hydrophobic area after passing through the hollow portion 10, preferably the viscosity of the above quantum dot ink is less than or equal to 50 cps, so the quantum dot ink may be dispersed better to fall into the sub-pixel area; in addition, in order to guarantee that the ink being effectively atomized by the nozzles, preferably, the above spray-coating process is ultrasonic spray-coating, in order to improve the spray-coating effect of the preferable hydrophilic ink or the hydrophobic ink, ultrasonic frequency used by the preferable ultrasonic spray-coating is 45-180 kHz, the viscosity of the preferable hydrophilic ink or hydrophobic ink is less than or equal to 10 cps.

The above hydrophilic ink includes hydrophilic quantum dots, and the hydrophilic quantum dots are quantum dots of which surface ligands contain hydrophilic groups, preferably the hydrophilic group is carboxyl, an amine, hydroxyl group or sulfydryl group; and the above hydrophobic ink includes hydrophobic quantum dots, and the hydrophobic quantum dots are quantum dots of which surface ligands contain hydrophobic groups, preferably the hydrophobic group is hydrocarbon chain or ester group; in order to achieve full-color display of the electroluminescence and photoluminescence combined light emitting device, preferably the quantum dots in the above quantum dot ink are red quantum dots and/or green quantum dots.

The above quantum dot ink with hydrophilicity/hydrophobicity may also include curable resin or monomers) thereof and a solvent (or named as a dispersing agent). The solvent may be selected from long chain hydrocarbon of which boiling point is between 40 and 250 DEG C., a mixture of alcohol, ester and ether as organic solvent. Preferably, the hydrocarbon is straight chain or branched chain alkane, for example, the hydrocarbon is C6-10 alkane. The organic solvent may be chlorobenzene, orthodichlorobenzene, tetrahydrofuran, anisole, morpholine, methylbenzene, ortho-xylene, m-xylene, p-xylene, alkylbenzene, nitrobenzene, normal hexane, cyclohexane, n-heptane, cycloheptane, dioxane, dichloromethane, trichloromethane, dichloroethane, chloroform, chlorobenzene, 1,4-dioxahexane, 1,2-dichloroethane, 1,1,1-trichloroethane, 1,1,2,2-tetrachloroethane, tetrahydronaphthalene, decalin, N,N-dimethylformamide, N,N-dimethylacetamide, dimethyl sulfoxide chloroform, tetrahydrofuran, dichloromethane, methylbenzene, normal hexane, methyl alcohol, ethyl alcohol, propyl alcohol, butyl alcohol, acetone, dioxane, dimethylformamide and dimethyl sulfoxide. The curable resin is selected from epoxy resin, acrylic resin, organic silicon resin, or the curable resin formed by crosslinking corresponding monomer(s). The above hydrophilic/hydrophobic quantum dot ink may further include a double bonded crosslinking agent, a photo curing agent or a heat curing agent or the like.

After the step c is executed, the step d is executed: the quantum dot ink in the hydrophilic areas or the hydrophobic areas is dried. Those skilled in the art may set the technical conditions of the above quantum dot ink drying process according to the prior art. In a preferable implementation mode, the manufacturing method further includes a process of repeatedly performing at least one time of steps b to d, in each time of the repeated process, the hollow portions of the used surface modified mask plate correspond to the hydrophilic areas or the hydrophobic areas, and the light emitting colors of the used quantum dot inks are different. In the above preferable implementation mode, by disposing the different light emitting colors of the quantum dot material inks on targeted area of the substrate and drying or solidifying, the final light emitting color of the light emitting device can be adjusted; and by disposing the red quantum dots and the green quantum dots in different sub-pixel areas, under the irradiation of blue backlight, the quantum dot film may realize the red and green photoluminescence, thus RGB full-color display can be realized.

According to another aspect of the application, a quantum dot film is further provided, the quantum dot film is manufactured by the above manufacturing method. Because the hydrophilic areas and the hydrophobic areas are formed on the first surface of the light transmitting substrate, and the surface modified mask plate is disposed on the first surface of the light transmitting substrate, the hollow portions are disposed corresponding to the hydrophilic areas or the hydrophobic areas, different quantum dot inks enters different pixel areas after passing through the surface modified mask plate, and multiple separated sub-pixel areas are formed on the surface of the light transmitting substrate with the hydrophilic areas and the hydrophobic areas on the light transmitting substrate, the hydrophilic quantum dot ink is enabled to enter the hydrophilic areas, then the hydrophobic areas are used as a separating structure, or the hydrophobic quantum dot ink enters the hydrophobic areas, then the hydrophilic areas are used as the separating structure, so the quantum dot ink color mixture between the different sub-pixel areas is effectively prevented; in addition, compared with the quantum dot film formed by disposing the pixel separating structure on the transparent substrate, the above quantum dot film has lower manufacturing cost.

According to another aspect of the application, a display device is further provided, the display device includes an electroluminescence device and the above quantum dot film disposed at the light emitting side of the electroluminescence device. Because the quantum dot film of the above display device is formed by forming hydrophilic areas and hydrophobic areas on the first surface of the light transmitting substrate, and disposing the above surface modified mask plate on the first surface of the light transmitting substrate, and making the hollow portions disposed corresponding to the hydrophilic areas or the hydrophobic areas, the quantum dot color mixture between different pixel areas of the quantum dot film is prevented, and the color accuracy of the display device with the quantum dot film is effectively improved.

In order to prevent the color mixture between the neighboring sub-pixel areas in the quantum dot film when the quantum dot film is irradiated by the electroluminescence device, preferably, the second modified surface opposite to the first modified surface of the light transmitting substrate of the quantum dot film or the blue backlight emitting side adhered to the second modified surface is provided with a black matrix, when the hydrophilic quantum dot ink enters the hydrophilic areas, the black matrix is disposed corresponding to the hydrophobic areas, and when the hydrophobic quantum dot ink enters the hydrophobic areas, the black matrix is disposed corresponding to the hydrophilic areas.

The light emitting device and the manufacturing method thereof provided by the disclosure are further described below in combination with embodiments.

Embodiment 1

A manufacturing method for a surface modified mask plate provided by the present embodiment includes the following steps:

step S101, the mask plate prepared by nickel alloy is immerged in solution with a hydrophobic material, the above hydrophobic material is heptadecafluorodecyl trimethoxy silane, so that the hydrophobic material is fixed on the surface of the mask plate;

step S102, the mask plate fixed with the hydrophobic material is separated from the solution, and the mask plate is dried or solidified to obtain the surface modified mask plate with hydrophobicity.

Embodiment 2

A manufacturing method for a substrate with hydrophilic areas and hydrophobic areas on a surface includes the following steps:

the coupling agent and the initiator are mixed in the solvent, to form substrate treating solution, the surface of one side of the light transmitting substrate is placed in the substrate treating solution, the coupling agent is bonding and fixing on the surface of the light transmitting substrate and a bonded surface is formed, the first reaction raw material is disposed on the bonded surface, the first reaction raw material positioned in the first area is covered, and ultraviolet irradiation is performed on the first reaction raw material positioned in the first area, so that a grafting reaction occurs between on the first reaction raw material and the coupling agent under the ultraviolet irradiation, then the hydrophobic areas are formed, the first reaction raw material in the first area is removed, and a second reaction raw material is disposed on the first area and the second shielding area, the second reaction raw material positioned in the second shielding area is covered, and the ultraviolet irradiation is performed on the second reaction raw material positioned in the first area, so the grafting reaction occurs between the second reaction raw material and the coupling agent under the ultraviolet irradiation, then the hydrophilic area is formed, and the surface modified mask plate is obtained;

wherein, the light transmitting substrate is glass, the coupling agent is chloro-(dimethyl)-vinylsilane, the initiator is 4-dimethylpyridine, the first reaction raw material is 1H,1H,2H,2H-perfluorodecyl mercaptan, the second reaction raw material is mercaptoethylamine, and the hydrophobic second areas corresponds to two groups of 96×64 micro-array patterns.

Embodiment 3

A manufacturing method for an electroluminescence device provided by the embodiment includes the following steps:

step S301, a first electrode substrate with a pixel separating structure is provided, the pixel separating structure has 96×64 mutually separated sub-pixel areas, the first electrode substrate is a substrate with an anode layer, and the anode layer is an ITO anode;

step S302, the surface modified mask plate provided in the embodiment 1 is disposed at one side of the first electrode substrate with the pixel separating structure, hollow portions of the mask plate correspond to the sub-pixel areas;

step S303, an inkjet printing (the type is Dimatix Materials Printer DMP-2831) process is used for enabling aqueous solution of PEDOT: PSS as hole injection layer ink to enter the corresponding sub-pixel area after passing through the hollow portions;

step S304, the hole injection layer ink in the sub-pixel areas is dried or solidified, so as to form the hole injection layer;

step S305, the steps of S302 to S304 are executed again, in the step S302 of the above repeated process, the mask plate prepared by the nickel alloy is used, in the step S303 of the above repeated process, hole transporting layer ink is used, and the hole transporting layer ink is toluene solution of poly-(9-vinyl) carbazole (PVK), then the hole transporting layer is formed in the step S304;

step S306, the steps of S302 to S304 are executed again, in the step S302 of the above repeated process, the mask plate prepared by the nickel alloy is used, in the step S303 of the above repeated process, green quantum dot material ink is used, and the green quantum dot material ink is decane solution of CdSe/CdS, so a green quantum dot light emitting area is formed in the step S304;

step S307, the steps of S302 to S304 are executed again, in the step S302 of the above repeated process, the mask plate prepared by the nickel alloy is used, in the step S303 of the above repeated process, red quantum dot material ink is used, and the red quantum dot material ink is decane solution of CdSe/ZdS, so a red quantum dot light emitting area is formed in the step S304;

step S308, the steps of S302 to S304 are executed again, in the step S302 of the above repeated process, the surface modified mask plate provided in the embodiment 1 is used, electron transporting layer ink and electron injection layer ink are used in the step S303 of the above repeated process, and the electron transporting layer ink and the electron injection layer ink are butanol solution of ZnO, electron transporting and injection layers are formed in the step S304;

step S309, one side of the electron injection layer away from the first electrode substrate is evaporated with a second electrode, the material for forming a cathode layer is Ag.

Embodiment 4

A difference between manufacturing methods provided by the embodiment and that provided by the embodiment 3 is:

an ultrasonic spray-coating process is used for enabling electron transporting and injection layer ink, quantum dot material ink, hole transporting layer ink and hole injection layer ink to respectively enter the sub-pixel areas, ultrasonic frequency of the above ultrasonic spray-coating process is 120 kHz.

Embodiment 5

A difference between manufacturing methods provided by the present embodiment and embodiment 4 is:

the ultrasonic frequency of the ultrasonic spray-coating process is 180 kHz.

Embodiment 6

A difference between manufacturing methods provided by the present embodiment and embodiment 4 is:

the ultrasonic frequency of the ultrasonic spray-coating process is 45 kHz.

Embodiment 7

A difference between manufacturing methods provided by the present embodiment and embodiment 4 is:

the ultrasonic frequency of the ultrasonic spray-coating process is 90 kHz.

Embodiment 8

A manufacturing method for a photoluminescence device provided by the embodiment includes the following steps:

step S801, the mask plate prepared by nickel alloy is disposed on the surface of the surface modified substrate of the embodiment 2, 96×64 hollow portions of the mask plate correspond to one group of 96×64 micro-array patterns of the hydrophobic areas;

step S802, an inkjet printing (the type is Dimatix Materials Printer DMP-2831) process is used for enabling hydrophobic red quantum dot ink to enter the hydrophobic areas after passing through the hollow portions;

step S803, the quantum dot ink in the hydrophobic areas is dried or solidified;

step S804, the above mask plate is disposed on the surface of the above surface modified substrate, 96×64 hollow portions of the mask plate correspond to another group of 96×64 micro-array patterns of the hydrophobic areas;

step S805, the inkjet printing (the type is Dimatix Materials Printer DMP-2831) process is used for enabling hydrophobic green quantum dot ink to enter the hydrophobic areas after passing through the hollow portions;

step S806, the quantum dot ink in the hydrophobic areas is dried or solidified,

wherein, the viscosity of the red and green quantum dot ink is 15 cps, red quantum dot material is CdSe/ZnS, and green quantum dot material is CdSe/CdS, hydrophobic ligands on the surfaces of the both quantum dots are oleic acid.

Embodiment 9

A difference between manufacturing methods provided by the present embodiment and the embodiment 8 is:

the viscosity of the red and green quantum dot ink used in the inkjet printing process is 5 cps.

Embodiment 10

A difference between manufacturing methods provided by the present embodiment and the embodiment 8 is:

an ultrasonic spray-coating process is used for enabling the hydrophobic red quantum dot ink and green quantum dot ink to enter the hydrophobic areas after passing through the hollow portions, the ultrasonic frequency of the above ultrasonic spray-coating process is 120 kHz.

Embodiment 11

A manufacturing method for a surface modified mask plate provided by the embodiment includes the following steps:

step S1101, the mask plate is immerged in solution with a hydrophobic material, the above hydrophobic material is heptadecafluorodecyl trimethoxy silane, so that the hydrophobic material is fixed on the surface of the mask plate;

step S1102, the mask plate fixed with the hydrophobic material is separated from the solution, and the mask plate is dried or solidified;

step S1103, a first photomask is disposed on a first surface of the mask plate with 96×64 hollow portions, the first photomask is formed by 96×64 first shielding portions and a first light transmitting portion connected with each first shielding portion, the first shielding portions correspond to the hollow portions in one-to-one way, and the area of each first shielding portion in one-to-one correspondence is greater than the area of each hollow portion, an UV lamp is used for emitting ultraviolet light with 185 nm and 254 nm of wavelengths and the ultraviolet light is on to perform 5 min of ultraviolet ozone photolysis oxidization on the first surface of the mask plate after passing through the first photomask, and the UV lamp is used for emitting the ultraviolet light with 185 nm and 254 nm of wavelengths and the ultraviolet light is on to perform 5 min of the ultraviolet ozone photolysis oxidization on a second surface opposite to the first surface of the mask plate, so that the surface irradiated by the light forms a hydrophilic surface, and the rest surface of the mask plate forms a hydrophobic surface, the hollow portions are surrounded by the hydrophobic surface.

Embodiment 12

A manufacturing method for a surface modified mask plate provided by the present embodiment includes the following steps:

step S1201, the mask plate is immerged in solution with a hydrophobic material, the above hydrophobic material is heptadecafluorodecyl trimethoxy silane, so that the hydrophobic material is fixed on the surface of the mask plate;

step S1202, the mask plate fixed with the hydrophobic material is separated from the solution, and the mask plate is dried or solidified;

step S1203, a second photomask is disposed on the mask plate with 96×64 hollow portions, the first photomask is formed by 96×64 second light transmitting portions and a second shielding portion connected with each second light transmitting portion, the second light transmitting portions correspond to the hollow portions in one-to-one way, and the area of each second light transmitting portion in one-to-one correspondence is greater than the area of each hollow portion, an UV lamp is used for emitting ultraviolet light with 185 nm and 254 nm of wavelengths and the ultraviolet light is on to perform 5 min of the ultraviolet ozone photolysis oxidization on the mask plate after passing through the second photomask, so that the surface of the mask plate corresponding to the second light transmitting portions forms the hydrophilic surface, and the rest surface of the mask plate forms the hydrophobic surface, the hollow portions are surrounded by the hydrophilic surface.

Embodiment 13

A manufacturing method for an electroluminescence device provided by the present embodiment includes the following steps:

step S1301, a first electrode substrate with a pixel separating structure is provided, the pixel separating structure has 96×64 mutually separated sub-pixel areas, the first electrode substrate is a substrate with an anode layer, and the anode layer is an ITO anode;

step S1302, the surface modified mask plate provided in the embodiment 12 is disposed at one side of the first electrode substrate with the pixel separating structure, hollow portions of the surface modified mask plate correspond to the sub-pixel areas, the surface modified mask plate is provided with a modified surface consisting of a hydrophilic surface and a hydrophobic surface, the hollow portions is surrounded by the hydrophilic surface, and the modified surface except the hydrophilic surface is the hydrophobic surface;

step S1303, an inkjet printing (the type is Dimatix Materials Printer DMP-2831) process is used for enabling aqueous solution of PEDOT: PSS as hole injection layer ink to enter the corresponding sub-pixel areas after passing through the hollow portion;

step S1304, the hole injection layer ink in the sub-pixel areas is dried or solidified, so as to form a hole injection layer;

step S1305, the steps of S1302 to S1304 are executed again, in the step S1302 of the above repeated process, the surface modified mask plate provided in the embodiment 11 is used, in the step S1303 of the above repeated process, hole transporting layer ink is used, and the hole transporting layer ink is toluene solution of poly-(9-vinyl) carbazole (PVK), so the hole transporting layer is formed in the step S1304;

step S1306, the steps of S1302 to S1304 are executed again, in the step S1302 of the above repeated process, the surface modified mask plate provided in the embodiment 11 is used, in the step S1303 of the above repeated process, quantum dot material ink is used, and the quantum dot material ink is decane solution of CdSe/CdS, so a light emitting layer is formed in the step S1304;

step S1307, the steps of S1302 to S1304 are executed again, in the step S1302 of the above repeated process, the surface modified mask plate provided in the embodiment 12 is used, in the step S1303 of the above repeated process, electron transporting layer ink and electron injection layer ink are used, and the transporting layer ink and the electron injection layer ink are butanol solution of ZnO, the electron transporting and injection layers are formed in the step S1304;

step S1308, one side of the electron injection layer away from the first electrode substrate is evaporated with a second electrode, the material for forming a cathode layer is Ag.

Embodiment 14

A difference between manufacturing methods provided by the present embodiment and embodiment 13 is:

an ultrasonic spray-coating process is used for enabling electron transporting and injection layer ink, quantum dot material ink, hole transporting layer ink and hole injection layer ink to respectively enter the sub-pixel areas, ultrasonic frequency of the above ultrasonic spray-coating process is 120 kHz.

Embodiment 15

A difference between manufacturing methods provided by the present embodiment and embodiment 14 is:

the ultrasonic frequency of the ultrasonic spray-coating process is 180 kHz.

Embodiment 16

A difference between manufacturing methods provided by the embodiment and embodiment 14 is:

the ultrasonic frequency of the ultrasonic spray-coating process is 45 kHz.

Embodiment 17

A difference between manufacturing methods provided by the embodiment and embodiment 14 is:

the ultrasonic frequency of the ultrasonic spray-coating process is 90 kHz.

Embodiment 18

A manufacturing method for the surface modified light transmitting substrate provided by the embodiment includes the following steps:

the coupling agent and the initiator are mixed in the solvent, to form substrate treating solution, the surface of one side of the light transmitting substrate is placed in the substrate treating solution, the coupling agent is bonding and fixing on the surface of the light transmitting substrate and a bonded surface is formed, the first reaction raw material is disposed on the bonded surface, the first reaction raw material positioned in the first area is covered, and ultraviolet irradiation is performed on the first reaction raw material positioned in the second area, so that a grafting reaction occurs between the first reaction raw material and the coupling agent under the ultraviolet irradiation, then the hydrophobic area is formed, the first reaction raw material in the first area is removed, and a second reaction raw material is disposed on the first area and the second shielding area, the second reaction raw material positioned in the second shielding area is covered, and the ultraviolet irradiation is performed on the second reaction raw material positioned in the first area, so the grafting reaction occurs between the second reaction raw material and the coupling agent under the ultraviolet irradiation, then the hydrophilic area is formed;

wherein, the light transmitting substrate is glass, the coupling agent is chloro-(dimethyl)-vinylsilane, the initiator is 4-dimethylpyridine, the first reaction raw material is 1H,1H,2H,2H-perfluorodecyl mercaptan, the second reaction raw material is mercaptoethylamine, and the hydrophobic second area corresponds to two groups of 96×64 micro-array patterns.

Embodiment 19

A manufacturing method for a quantum dot film provided by the embodiment adopts the surface modified mask plate of the embodiment 11 and the surface modified light transmitting substrate of the embodiment 18, the manufacturing method includes the following steps:

step S1901, the surface modified mask plate is disposed on the first surface, 96×64 surface modified hollow portions correspond to one group of 96×64 micro-array patterns of the hydrophobic areas;

step S1902, an inkjet printing (the type is Dimatix Materials Printer DMP-2831) process is used for enabling hydrophobic red quantum dot ink to enter the hydrophobic areas after passing through the hollow portions;

step S1903, the quantum dot ink in the hydrophobic areas is dried or solidified;

step S1904, the surface modified mask plate is disposed on the first surface, 96×64 surface modified hollow portions correspond to another group of 96×64 micro-array patterns of the hydrophobic areas;

step S1905, the inkjet printing (the type is Dimatix Materials Printer DMP-2831) process is used for enabling hydrophobic green quantum dot ink to enter the hydrophobic areas after passing through the hollow portions;

step S1906, the quantum dot ink in the hydrophobic area is dried or solidified,

herein, the viscosity of the red and green quantum dot ink is 15 cps, a red quantum dot material is CdSe/ZnS, and a green quantum dot material is CdSe/CdS, hydrophobic ligands on the surfaces of the both quantum dots are oleic acid.

Embodiment 20

A difference between manufacturing methods provided by the present embodiment and embodiment 19 is:

the viscosity of the red and green quantum dot ink used in the inkjet printing process is 5 cps.

Embodiment 21

A difference between manufacturing methods provided by the present embodiment and embodiment 19 is:

an ultrasonic spray-coating process is used for enabling the hydrophobic red quantum dot ink and green quantum dot ink to enter the hydrophobic areas after passing through the hollow portions, the ultrasonic frequency of the above ultrasonic spray-coating process is 120 kHz.

Embodiment 22

A difference between manufacturing methods provided by the present embodiment and embodiment 21 is:

the ultrasonic frequency of the ultrasonic spray-coating process is 45 kHz.

Comparison Example 1

A manufacturing method for an electroluminescence device provided by the comparison example includes the following steps:

step Sd101, a first electrode substrate with a pixel separating structure is provided, the pixel separating structure has 96×64 mutually separated sub-pixel areas, the first electrode substrate is a substrate with an anode layer;

step Sd102, an inkjet printing (the type is Dimatix Materials Printer DMP-2831) process is used for enabling hole injection layer ink to enter the sub-pixel area;

step Sd103, the hole injection layer ink in the sub-pixel area is dried or solidified, so as to form a hole injection layer;

step Sd104, the steps of Sd102 to Sd103 are executed again, in the step Sd103 of the above repeated process, hole transporting layer ink, quantum dot material ink, and electron transporting layer ink are respectively used, so a hole transporting layer, a light emitting layer and an electron transporting layer are formed in a sequence during the step Sd104;

step Sd105, one side of the electron transporting layer away from the first electrode substrate is provided with a second electrode,

wherein, the hole transporting layer ink, the electron transporting layer ink, the quantum dot material ink, the hole transporting layer ink and the hole injection layer ink are the same as those of the embodiment 3.

Comparison Example 2

A manufacturing method for a photoluminescence device provided by the comparison example includes the following steps:

step Sd201, a first surface of a light transmitting substrate is coated with a photoresist, and exposure and development processes are successively performed to form a pixel separating structure, the pixel separating structure has two groups of 96×64 mutually separated sub-pixel areas, and the naked surface of the pixel separating structure is hydrophilic surface, the neighboring side walls of the separating matrix of the pixel separating structure is perpendicular to the substrate, the separating matrix between the neighboring side walls is a separating bar, and one side of the surface of the separating bar away from the substrate is a plane;

step Sd202, a light transmitting substrate of the pixel separating structure is spin-coated by a red quantum dot material, and baking treatment, exposure treatment, development treatment and drying treatment are successively performed on the light transmitting substrate provided with the red quantum dot material, and 96×64 red quantum dot arrays are obtained;

step Sd203, the above substrate is spin-coated by a green quantum dot material, and the baking treatment, exposure treatment, development treatment and drying treatment are successively performed on the light transmitting substrate provided with the green quantum dot material, and 96×64 red quantum dot arrays are obtained,

wherein, the light transmitting substrate is glass, the red quantum dot material includes CdSe/ZnS, the green quantum dot material includes CdSe/CdS, and the viscosity of the quantum dot material ink is 15 cps.

Comparison Example 3

A manufacturing method for an electroluminescence device provided by the comparison example includes the following steps:

step Sd301, a first electrode substrate with a pixel separating structure is provided, the pixel separating structure has 96×64 mutually separated sub-pixel areas, the first electrode substrate is a substrate with an anode layer;

step Sd302, a precision inkjet printing device (a Jetlabll high-precision nanomaterial deposition inkjet printing system) is used for enabling hole injection layer ink to enter the sub-pixel areas;

step Sd303, the hole injection layer ink in the sub-pixel area is dried, so as to form the hole injection layer;

step Sd304, the steps of Sd302 to Sd303 are executed again, in the step Sd303 of the above repeated process, hole transporting layer ink, quantum dot material ink, and electron transporting layer ink are respectively used, so a hole transporting layer, a light emitting layer and an electron transporting layer are formed in a sequence during the step Sd304;

step Sd305, one side of the electron transporting layer away from the first electrode substrate is provided with a second electrode,

wherein, the hole transporting layer ink, the electron transporting layer ink, the quantum dot material ink, the hole transporting layer ink and the hole injection layer ink are the same as those of the embodiment 13.

Power-on tests were performed on the electroluminescence devices of the above embodiments 3 to 7 and the comparison example 1, a circuit controls only red sub-pixels or green sub-pixels to emit light independently, and a scanning spectroradiometer (PR670) is used for uniformly selecting two positions on the electroluminescence device for testing color coordinates thereof, the test results are as shown in table 1.

TABLE 1 Embodiment R1 (x, y) R2 (x, y) G1 (x, y) G2 (x, y) Embodiment 3 0.6750, 0.6751, 0.1875, 0.1888, 0.3222 0.3223 0.7415 0.7431 Embodiment 4 0.6752, 0.6755, 0.1898, 0.1885, 0.3220 0.3224 0.7435 0.7431 Embodiment 5 0.6755, 0.6753, 0.1936, 0.1945, 0.3221 0.3229 0.7425 0.7418 Embodiment 6 0.6749, 0.6754, 0.1882, 0.1877, 0.3225 0.3220 0.7418 0.7434 Embodiment 7 0.6751, 0.6748, 0.1910, 0.1900, 0.3224 0.3225 0.7410 0.7435 Embodiment 1 0.6032, 0.6147, 0.3117, 0.3097, 0.3026 0.3004 0.5616 0.5775

It may be apparently observed from the above test results that the electroluminescence devices obtained by the manufacturing process of using the combination of the regular inkjet printing and the mask plate or the combination of the ultrasonic spray-coating and the mask plate of the above embodiments 3 to 7 have better consistency of the color coordinates; and the change of the color coordinates of the electroluminescence device obtained by only using the manufacturing process of the regular inkjet printing in the above comparison example 1 is extremely large, and an apparent color mixture phenomenon can be observed from values of the color coordinates.

In addition, after sealing protecting layers are respectively applied to the photoluminescence devices in the above embodiments 8 to 10 and the comparison example 2, the photoluminescence devices are disposed at the light emitting side of a blue electroluminescence device (BOLED), a control circuit only allows blue backlight corresponding to the red sub-pixel or the green sub-pixel to emit light independently, under the excitation of blue light, the corresponding red quantum dots or green quantum dots generate photoluminescence, the scanning spectroradiometer (PR670) is used for uniformly selecting two positions on the light emitting surface for testing the color coordinates thereof, the test results are as shown in table 2.

TABLE 2 Embodiment R1 (x, y) R2 (x, y) G1 (x, y) G2 (x, y) Embodiment 8 0.6755, 0.6752, 0.1898, 0.1878, 0.3219 0.3225 0.7454 0.7424 Embodiment 9 0.6751, 0.6751, 0.1870, 0.1904, 0.3220 0.3225 0.7473 0.7427 Embodiment 10 0.6745, 0.6755, 0.1941, 0.1936, 0.3222 0.3214 0.7429 0.7425 Comparison 0.6748, 0.6754, 0.1895, 0.1889, example 2 0.3225 0.3230 0.7447 0.7456

It may be apparently observed from the above test result that the photoluminescence devices obtained by the manufacturing process of using the combination of the regular inkjet printing and the mask plate or the combination of the ultrasonic spray-coating and the mask plate have better consistency of the color coordinates, and the consistency is equivalent to that of the photoluminescence device obtained by conventional exposure and development method in the above comparison example 2, however the preparation cost is reduced.

An optical microscope is used for acquiring an optical microscope diagram of the sub-pixel area after the step S1306 is executed in the embodiment 13, in a dark environment, the UV lamp with 365 nm wavelength is used for irradiating the quantum dots to generate photoluminescence, as shown in FIG. 4, it may be observed from the figure that the red quantum dot ink is basically positioned in the sub-pixel areas, the shape is regular, and the irrelevant area has no ink residue; and the scanning spectroradiometer (PR670) is used for testing the photoelectric properties of the electroluminescence devices in the above embodiments 13 to 17 and the comparison example 3, the test results are as shown in table 3 below:

TABLE 3 Name External Quantum Efficiency (EQE) % Embodiment 13 11.24 Embodiment 14 11.18 Embodiment 15 11.48 Embodiment 16 11.16 Embodiment 17 11.46 Comparison example 3 11.36

It may be observed from the above test results that the photoelectric properties of the electroluminescence devices obtained by the manufacturing process of using the combination of regular inkjet printing and the mask plate or the combination of the ultrasonic spray-coating and the mask plate are equivalent to that of the electroluminescence devices prepared by precision inkjet printing.

Comparison Example 4

A manufacturing method for a photoluminescence quantum dot film provided by the comparison example includes the following steps:

step Sd401, a first surface of a light transmitting substrate is coated with a photoresist, and exposure and development processes are successively performed to form a pixel separating structure, the pixel separating structure has two groups of 96×64 mutually separated sub-pixel areas, and the naked surface of the pixel separating structure is hydrophilic surface, the neighboring side walls of the separating matrix of the pixel separating structure is perpendicular to the substrate, the separating matrix between the neighboring side walls is a separating bar, and the surface of one side of the separating bar away from the substrate is a plane;

step Sd402, the surface modified mask plate is disposed on the first surface, 96×64 hollow portions of the mask plate correspond to a group of the sub-pixel areas;

step Sd403, an inkjet printing process is used for enabling hydrophobic red quantum dot ink to enter a hydrophobic areas after passing through the hollow portions;

step Sd404, the red quantum dot ink in the hydrophobic areas is dried;

step Sd405, the surface modified mask plate is disposed on the first surface, 96×64 hollow portions of the mask plate correspond to another group of the sub-pixel areas;

step Sd406, the inkjet printing process is used for enabling hydrophobic green quantum dot ink to enter the hydrophobic areas after passing through the hollow portions;

step Sd407, the green quantum dot ink in the hydrophobic area is dried,

wherein, the light transmitting substrate is glass, a material forming the above naked surface is polyimide, the red quantum dot material ink includes CdSe/ZnS, the green quantum dot material includes CdSe/CdS, and the viscosity of the quantum dot material ink is 15 cps.

Comparison Example 5

A difference between the manufacturing methods provided by the present comparison example and comparison example 4 is that: by separately spin-coating red and green quantum dot materials, the red and green color alternated quantum dot film is obtained through multiple times of exposure and development, the method specifically includes the following steps:

step Sd501, a light transmitting substrate with a pixel separating structure is spin-coated by red quantum dot material, and baking treatment, exposure treatment, development treatment and drying treatment are successively performed on the light transmitting substrate provided with the red quantum dot material;

step Sd502, the above substrate is spin-coated by green quantum dot material, and the baking treatment, exposure treatment, development treatment and drying treatment are successively performed on the light transmitting substrate provided with the green quantum dot material,

wherein, 96×64 red quantum dot arrays and 96×64 green quantum dot arrays are respectively obtained in the step Sd501 and the step Sd502.

After sealing protecting layers are respectively applied to the quantum dot films of the above embodiments 19 to 22 and the comparison examples 4 to 5, the quantum dot film is disposed at the light emitting side of a blue electroluminescence device (BOLED), the electroluminescence device includes a blue LED lamp bead packaged by epoxy resin and a light diffusion plate stacked in sequence. An integrating sphere is used for integrating the photoluminescence spectrum areas of the red and green quantum dots, the obtained photoluminescence efficiencies of the red and green quantum dots are as shown in table 4 below:

TABLE 4 Photoluminescence Photoluminescence efficiencies of the efficiencies of the Embodiment No. red quantum dots green quantum dots Embodiment 19 41% 32% Embodiment 20 46% 36% Embodiment 21 45% 37% Embodiment 22 43% 33% Comparison example 4 44% 35% Comparison example 5 42% 31%

It may be observed from the above test results that the photoluminescence efficiencies of the red quantum dot and the green quantum dot obtained by the implementation modes of the disclosure are equivalent to those of traditional process, or even better, however the manufacturing cost is greatly reduced.

It may be observed from the above description that the above embodiments of the disclosure realize the following technical effects:

1, a technical scheme of the combination of the mask plate and the solution method is used for forming a light emitting layer or a functional layer, the mask plate is used for preventing ink from being dispersed to other color areas, a color mixture problem is effectively avoided, and the color accuracy of the light emitting device is improved;

2, through the combination of the pixel separating structure and the mask plate, a spray-coating process of the solution method may be used for manufacturing the pixels, and an inkjet printing device in lower precision may be used for manufacturing the pixels, the required cost of using a precision inkjet printing device is reduced;

3, the mask plate with the modified surface may be used for enabling ink with different hydrophobicity-hydrophilicity to accurately enter the corresponding sub-pixel area, and the pixel separating structure is used for preventing the ink color mixture between the different sub-pixel areas, because the mask plate is placed and used above the pixel separating structure, in the manufacturing of large area display, the peripheral area of the hollow portions is not easily deformed because of the support of the pixel separating structure, so color difference or other performance problems which are caused by different injection quantities of the ink in the different sub-pixel areas or the injection deviation are effectively solved;

4, through hydrophilic areas and hydrophobic areas on a light transmitting substrate, multiple separated sub-pixel areas are formed on the surface of the light transmitting substrate, the hydrophilic quantum dot ink is enabled to enter the hydrophilic areas, the hydrophobic areas are used as a separating structure, or the hydrophobic quantum dot ink enters the hydrophobic areas, and the hydrophilic areas are used as the separating structure, thereby a problem that the color accuracy is reduced because of the quantum dot ink color mixture in the different sub-pixel areas is effectively solved;

5, compared with a manufacturing method for disposing the pixel separating structure on a transparent substrate, the above manufacturing method of the application enables the ink to be injected to the desired sub-pixel areas, and to reduce the manufacturing cost of the quantum dot film.

The above are only the preferable embodiments of the disclosure, and have no intention to limit the disclosure, it is to be noted by those skilled in the art that the disclosure may have various modifications and variations. Any modifications, equivalent replacements, improvements and the like made within the spirit and principle of the disclosure shall fall within the scope of protection of the disclosure. 

What is claimed is:
 1. A manufacturing method for a light emitting device, comprising the following steps: step S1: disposing a mask plate having a plurality of hollow portions on a substrate; step S2: by solution method, applying ink on a surface of the substrate through the hollow portions; and step S3: drying or solidifying the ink on the surface of the substrate to form a light emitting layer or a functional layer.
 2. The manufacturing method as claimed in claim 1, wherein the ink is quantum dot material ink, the manufacturing method further comprises a process of at least one time of repeatedly performing the step S1 to the step S3, in each time of the repeated process, the hollow portions of the used mask plate correspond to different areas of the substrate, the light emitting colors of the used inks are different.
 3. The manufacturing method as claimed in claim 1, wherein the mask plate in the step S1 has a modified surface, the modified surface includes a surface of one side of the mask plate away from the substrate, the modified surface has hydrophilicity or hydrophobicity; and the ink used in the step S2 and the modified surface have different hydrophilicity-hydrophobicity.
 4. The manufacturing method as claimed in claim 3, wherein the modified surface further comprises a surface of one side of the mask plate adjacent to the substrate.
 5. The manufacturing method as claimed in claim 4, wherein when the modified surface is a hydrophobic surface, the manufacturing method further comprises a process of forming the modified surface, the process of forming the modified surface includes the following steps: step S01, immerging the mask plate in a solution with a hydrophobic material, so that the hydrophobic material is fixed on the surface of the mask plate, preferably the hydrophobic material is a fluoric silane coupling agent; and step S02, separating the mask plate fixed with the hydrophobic material from the solution, and drying the mask plate, so as to form the modified surface with hydrophobicity.
 6. The manufacturing method as claimed in claim 1, wherein the manufacturing method further comprises a process of pre-processing the mask plate, the pre-processing process comprises the following steps: performing ultraviolet ozone photolysis oxidization on the surface of the mask plate, so that the hydrophilic surface of the mask plate is completely exposed.
 7. The manufacturing method as claimed in claim 1, wherein the substrate in the step S1 is provided with a pixel separating structure, and the pixel separating structure is provided with multiple mutually separated sub-pixel areas, and the hollow portions are disposed corresponding to each sub-pixel areas; and in the step S2, the ink enters the corresponding sub-pixel areas after passing through the hollow portions.
 8. The manufacturing method as claimed in claim 1, wherein the surface of the substrate in the step S1 has a plurality of hydrophilic areas and a plurality of hydrophobic areas, the hollow portions are disposed corresponding to the hydrophilic areas or the hydrophobic areas; and in the step S2, the hydrophobic ink enters the hydrophobic areas after passing through the hollow portions, or the hydrophilic ink enters the hydrophilic areas after passing through the hollow portions.
 9. The manufacturing method as claimed in claim 1, wherein the ink is any one of hole injection material ink, hole transporting material ink, electron injection material ink or electron transporting material ink, in the step S3, the ink is dried, so as to correspondingly form a hole injection layer, a hole transporting layer, an electron injection layer or an electron transporting layer; or the ink is quantum dot material ink or organic light emitting material ink, in the step S3, the ink is dried, so as to correspondingly form a quantum dot light emitting layer or an organic light emitting layer.
 10. The manufacturing method as claimed in claim 1, wherein the ink is electrode material ink, in the step S3, the ink is dried, so as to form a corresponding electrode layer.
 11. The manufacturing method as claimed in claim 1, wherein the ink is any one of hole injection material ink, hole transporting material ink, electron injection material ink, electrode material ink or electron transporting material ink, in the step S3, the ink is solidified, so as to correspondingly form a hole injection layer, a hole transporting layer, an electron injection layer, an electrode layer or an electron transporting layer; or the ink is quantum dot material ink or organic light emitting material ink, in the step S3, the ink is solidified, so as to correspondingly form a quantum dot light emitting layer or an organic light emitting layer.
 12. The manufacturing method as claimed in claim 1, wherein in the step S2, a spray-coating process or an inkjet printing process is used so that the ink is disposed on the surface of the substrate after passing through the hollow portions.
 13. A light emitting device, wherein the light emitting device is prepared by the manufacturing method as claimed in claim 1, wherein the light emitting device is an electroluminescence device or a photoluminescence device.
 14. A hybrid light emitting device, wherein the hybrid light emitting device comprise an electroluminescence device and a photoluminescence device disposed at the light emitting side of the electroluminescence device, wherein the electroluminescence device and/or the photoluminescence device is prepared according to the manufacturing method as claimed in claim
 1. 15. The manufacturing method as claimed in claim 2, wherein the mask plate in the step S1 has a modified surface, the modified surface includes a surface of one side of the mask plate away from the substrate, the modified surface has hydrophilicity or hydrophobicity; and the ink used in the step S2 and the modified surface have different hydrophilicity-hydrophobicity.
 16. The manufacturing method as claimed in claim 2, wherein the manufacturing method further comprises a process of pre-processing the mask plate, the pre-processing process comprises the following steps: performing ultraviolet ozone photolysis oxidization on the surface of the mask plate, so that the hydrophilic surface of the mask plate is completely exposed.
 17. The manufacturing method as claimed in claim 2, wherein the substrate in the step S1 is provided with a pixel separating structure, and the pixel separating structure is provided with multiple mutually separated sub-pixel areas, and the hollow portions are disposed corresponding to each sub-pixel areas; and in the step S2, the ink enters the corresponding sub-pixel areas after passing through the hollow portions.
 18. The manufacturing method as claimed in claim 2, wherein the surface of the substrate in the step S1 has a plurality of hydrophilic areas and a plurality of hydrophobic areas, the hollow portions are disposed corresponding to the hydrophilic areas or the hydrophobic areas; and in the step S2, the hydrophobic ink enters the hydrophobic areas after passing through the hollow portions, or the hydrophilic ink enters the hydrophilic areas after passing through the hollow portions.
 19. The manufacturing method as claimed in claim 2, wherein in the step S2, a spray-coating process or an inkjet printing process is used so that the ink is disposed on the surface of the substrate after passing through the hollow portions.
 20. The manufacturing method as claimed in claim 1, wherein the spray-coating process is ultrasonic spray-coating. 